EMBRACE II study protocol v.1.0
Image guided intensity modulated External beam radiochemotherapy and
MRI based adaptive BRAchytherapy in locally advanced CErvical cancer
EMBRACE-II
Protocol writing committee: Kari Tanderup, Richard Pötter, Jacob Lindegaard, Christian Kirisits, Ina Juergenliemk-Schulz, Astrid de Leeuw, Israël Fortin, Kathrin Kirchheiner, Dietmar Georg, Remi Nout, Yvette Seppenwoolde, Wolfgang Dörr, Thomas Liederer, Li Tee Tan
CONTENTS 1
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Contents __________________________________________________________________________________ 1 3
1 Abbreviations ___________________________________________________________________________ 6 4
2 Summary ______________________________________________________________________________ 8 5
2.1 Background __________________________________________________________________________________ 8 6
2.2 Interventions, aims and hypotheses ______________________________________________________________ 8 7
2.3 Type of design ________________________________________________________________________________ 9 8
2.4 Patients to be included _________________________________________________________________________ 9 9
2.5 Treatment of patients in the trial _________________________________________________________________ 9 10
2.6 Quality assurance ____________________________________________________________________________ 10 11
2.7 Outcome measures ___________________________________________________________________________ 10 12
2.8 Evaluation of outcome measures ________________________________________________________________ 10 13
2.9 Sample size and data maturity __________________________________________________________________ 11 14
3 Introduction ___________________________________________________________________________ 12 15
3.1 Background _________________________________________________________________________________ 12 16
3.2 Tumor and target CONCEPTS FOR RESPONSE ADAPTED RADIOTHERAPY in cervix cancer: residual GTV-T, 17
adaptive CTV-THR and CTV-TIR _________________________________________________________________________ 13 18
3.3 Evidence from the retroEMBRACE and EMBRACE studies ____________________________________________ 17 19
3.3.1 Local control and D90 to CTVHR, GTV and CTVIR ___________________________________________________________ 17 20
3.3.2 Overall treatment time _____________________________________________________________________________ 19 21
3.3.3 Urinary morbidity and bladder D2cm3 ___________________________________________________________________ 19 22
3.3.4 Rectal bleeding and rectum D2cm3 _____________________________________________________________________ 20 23
3.3.5 Bowel morbidity and sigmoid/bowel D2cm3 ______________________________________________________________ 20 24
3.3.6 Vaginal morbidity and ICRU recto-vaginal dose __________________________________________________________ 21 25
3.3.7 Gastrointestinal/urinary morbidity and intermediate dose levels related to EBRT _______________________________ 21 26
3.3.8 Patterns of spread and PROGNOSTIC PARAMETERS for nodal pelvic and para-aortic recurrences ___________________ 22 27
3.3.9 Administration of chemotherapy ______________________________________________________________________ 24 28
3.4 Internal target motion _________________________________________________________________________ 25 29
4 Interventions and Aims __________________________________________________________________ 26 30
4.1 Interventions ________________________________________________________________________________ 26 31
4.1.1 increased use of IC/IS technique in BT __________________________________________________________________ 26 32
4.1.2 Reduction of vaginal source loading ___________________________________________________________________ 27 33
4.1.3 Systematic Utilisation of IMRT ________________________________________________________________________ 27 34
4.1.4 Utilisation of daily IGRT (set-up according to bony structures) ______________________________________________ 28 35
4.1.5 EBRT target concept related to the primary tumour (CTV-T) and internal motion; Concepts for OAR contouring _______ 28 36
4.1.6 EBRT dose prescription and reporting __________________________________________________________________ 28 37
4.1.7 Adaptation of EBRT nodal elective CTV according to risk of nodal and systemic recurrence _______________________ 28 38
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4.1.8 Systematic application of simultaneous chemotherapy ____________________________________________________ 29 39
4.1.9 Reduction of overall treatment time ___________________________________________________________________ 29 40
4.2 Aims of the EMBRACE II study __________________________________________________________________ 30 41
4.2.1 General aims ______________________________________________________________________________________ 30 42
4.2.2 Specific aims ______________________________________________________________________________________ 30 43
5 Study design, endpoints and hypotheses ____________________________________________________ 31 44
5.1 Study design _________________________________________________________________________________ 31 45
5.2 Estimate of patient accrual and study period ______________________________________________________ 31 46
5.3 Hypotheses and endpoints _____________________________________________________________________ 31 47
5.3.1 General hypothesis on overall survival _________________________________________________________________ 32 48
5.3.2 Specific hypotheses on technique, dose and volumes: _____________________________________________________ 32 49
5.3.3 Specific hypotheses on clinical endpoints _______________________________________________________________ 33 50
6 EMBRACE Outline _______________________________________________________________________ 37 51
7 Staging and patient work-up ______________________________________________________________ 38 52
8 Patient selection ________________________________________________________________________ 39 53
8.1 Inclusion criteria _____________________________________________________________________________ 39 54
8.2 Exclusion criteria _____________________________________________________________________________ 39 55
9 External Beam Radiotherapy ______________________________________________________________ 40 56
9.1 Introduction _________________________________________________________________________________ 40 57
9.1.1 Aims of external Beam Radiotherapy (compare ch 3-5) ____________________________________________________ 40 58
9.1.2 Nodal targets based on risk group allocation for nodal spread ______________________________________________ 40 59
9.2 Preparations for treatment planning _____________________________________________________________ 42 60
9.3 Tumor and Target definition and contouring: Initial GTV, initial HR CTV-t, initial LR CTV-T, ITV-T; GTV-N, CTV-N, 61
CTV-E; PTV ________________________________________________________________________________________ 44 62
9.3.1 GENERAL Overview ________________________________________________________________________________ 44 63
9.3.2 Initial GTV and CTV related to primary tumour (GTV-Tinit, CTV-Tinit (HR, LR)) ____________________________________ 46 64
9.3.3 GTV and CTV for pathologic lymph nodes (GTV-N, CTV-N) __________________________________________________ 50 65
9.3.4 CTV for nodal regions with assumed microscopic disease (CTV-E) ____________________________________________ 50 66
9.3.5 ITV (ITV-T) ________________________________________________________________________________________ 51 67
9.3.6 Strategies to derive the ITV-T LR ______________________________________________________________________ 51 68
9.3.7 Generating the ITV45 _______________________________________________________________________________ 52 69
9.3.8 PTV _____________________________________________________________________________________________ 52 70
9.4 Contouring of organs at risk, reference points _____________________________________________________ 54 71
9.5 Contouring of Tumour, Targets and OARs based on MRI and CT _______________________________________ 54 72
9.6 Dose and fractionation for PTV45 _______________________________________________________________ 55 73
9.7 Dose and fractionation for PTV-N (nodal boosting) _________________________________________________ 55 74
9.8 Technique and procedures for EBRT including daily image guidance ___________________________________ 56 75
9.8.1 Angulation of the pelvis in relation to the lumbar spine ____________________________________________________ 57 76
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9.9 Planning aims for targets and organs at risk _______________________________________________________ 57 77
9.10 Reporting of EBRT parameters ________________________________________________________________ 58 78
10 BRACHYTHERAPY _____________________________________________________________________ 59 79
10.1 Introduction and specific aims for brachytherapy _________________________________________________ 59 80
10.1.1 Overall Schedule for EBRT and BT and chemotherapy _____________________________________________________ 59 81
10.1.2 Pre-application treatment planning ____________________________________________________________________ 60 82
10.2 Applicator insertion for brachytherapy _________________________________________________________ 60 83
10.3 Imaging for brachytherapy ___________________________________________________________________ 61 84
10.4 Applicator reconstruction and dose points for OARS ______________________________________________ 62 85
10.5 Contouring for brachytherapy: OARS, GTVres, adaptive CTVHR, CTVIR __________________________________ 64 86
10.5.1 Contouring of organs at risk __________________________________________________________________________ 64 87
10.5.2 Contouring of target volumes ________________________________________________________________________ 65 88
10.6 Treatment planning for brachytherapy _________________________________________________________ 66 89
10.6.1 Evidence obtained from retroEMBRACE and EMBRACE I ___________________________________________________ 66 90
10.6.2 Planning aims and dose prescription for EMBRACE II ______________________________________________________ 67 91
10.6.3 Dose optimisation for brachytherapy __________________________________________________________________ 67 92
10.6.4 Intracavitary treatment plans should be based on iterative steps ____________________________________________ 68 93
10.6.5 Vaginal dose de-escalation___________________________________________________________________________ 68 94
10.6.6 PTV and dose conformality considerations in relation to brachytherapy _______________________________________ 69 95
10.7 Dose and volume recording and reporting _______________________________________________________ 70 96
11 Systemic treatment ____________________________________________________________________ 71 97
11.1 Aims for chemotherapy ______________________________________________________________________ 71 98
11.2 Concomitant chemotherapy __________________________________________________________________ 71 99
11.3 Adjuvant chemotherapy _____________________________________________________________________ 71 100
12 Outcome assessment __________________________________________________________________ 73 101
12.1 Oncological outcome and salvage treatment ____________________________________________________ 73 102
12.2 Morbidity _________________________________________________________________________________ 74 103
12.3 Quality of Life (QoL) _________________________________________________________________________ 75 104
13 Translational research _________________________________________________________________ 76 105
13.1 Prognostic markers _________________________________________________________________________ 76 106
13.2 Predictive markers for radiotherapy related morbidity ____________________________________________ 76 107
14 Patient material, benchmarking, validation, evaluation and statistics ___________________________ 78 108
14.1 Benchmark of outcome and treatment related parameters _________________________________________ 78 109
14.2 Validation of dose and volume effects __________________________________________________________ 78 110
14.3 Exploration and Evaluation of dose and volume effects ____________________________________________ 78 111
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14.4 Identification of prognostic and predictive parameters ____________________________________________ 78 112
14.5 Statistics __________________________________________________________________________________ 78 113
15 Accreditation, dummy run, data monitoring, quality assurance and continuous education __________ 80 114
15.1 Commitment letter, compliance questionnaire and process document _______________________________ 80 115
15.2 Dummy run _______________________________________________________________________________ 80 116
15.2.1 Training, registration, and submission __________________________________________________________________ 81 117
15.2.2 Evaluation by study coordinators _____________________________________________________________________ 81 118
15.3 Data monitoring ____________________________________________________________________________ 81 119
15.4 Continuous education _______________________________________________________________________ 82 120
16 Patient enrollment procedure ___________________________________________________________ 83 121
17 Case record forms, procedures for data collection, EMBRACE II database ________________________ 84 122
18 Ethical considerations __________________________________________________________________ 85 123
18.1 PATIENT PROTECTION ____________________________________________________________________ 85 124
18.2 SUBJECT IDENTIFICATION _________________________________________________________________ 85 125
18.3 INFORMED CONSENT _____________________________________________________________________ 85 126
18.4 ADVANTAGES AND DISADVANTAGE FOR THE PATIENTS _____________________________________ 85 127
19 PUBLICATION OF DATA _________________________________________________________________ 86 128
20 Study office, Study coordinators, Study structure, communication ______________________________ 86 129
20.1 Study-office EMBRACE II Vienna (at present: 09/2015): ____________________________________________ 87 130
20.2 Study Coordination: _________________________________________________________________________ 87 131
21 EMBRACE RESEARCH GRoup ____________________________________________________________ 88 132
22 AppendiCES __________________________________________________________________________ 89 133
22.1 Appendix 1 Standard Clinical Diagram ________________________________________________________ 89 134
22.2 Appendix 2 Gyn GEC ESTRO Recommendations I-IV, ICRU 88 _______________________________________ 91 135
22.3 Appendix 3. Compliance questionnaire _________________________________________________________ 93 136
22.4 Appendix 4. Clinical cases for contouring ________________________________________________________ 97 137
22.4.1 Cases from Vienna, Utrecht and Aarhus, contouring tables _________________________________________________ 97 138
22.5 Appendix 5: EBRT contouring atlas (complement to chapter 9) _____________________________________ 98 139
22.5.1 Introduction ______________________________________________________________________________________ 98 140
22.5.2 Clinical Target Volumes related to the primary tumor _____________________________________________________ 98 141
22.5.3 Fixed margin approach ______________________________________________________________________________ 99 142
22.5.4 individualized approach ____________________________________________________________________________ 103 143
22.5.5 Clinical Target Volumes for nodal metastases and nodal regions ____________________________________________ 105 144
22.5.6 Para-aortic nodes _________________________________________________________________________________ 109 145
22.5.7 Inguinal nodes ___________________________________________________________________________________ 109 146
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22.5.8 Planning Target Volumes (PTV) ______________________________________________________________________ 110 147
22.5.9 nodal boost ______________________________________________________________________________________ 111 148
22.5.10 Primary target contouring summary with diagnostic MRI* ______________________________________________ 112 149
22.5.11 Primary target contouring summary with an MRI in treating position ______________________________________ 113 150
22.5.12 Contouring of organs at risk _______________________________________________________________________ 117 151
22.5.13 For para-aortic irradiation in addition _______________________________________________________________ 119 152
22.6 Appendix 6: Measurement and reporting of SUV ________________________________________________ 122 153
22.7 Appendix 8: CRFs (ch 16) ____________________________________________________________________ 122 154
22.8 Appendix 9: Principals and structures of EMBRACE RESEARCH GROUP _______________________________ 122 155
22.9 Appendix 10: Patient Information ____________________________________________________________ 124 156
23 References __________________________________________________________________________ 128 157
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1 ABBREVIATIONS 159 160 161 18F-FDG Fluorine 18 - Fluorodeoxyglucose 162
2/3/4D Two/Three/Four-dimensional 163
ACT Addenbrooke’s Contouring Tool 164
ATRAB Applied and Translational Radiobiology (Medical University Vienna) 165
AUC Area Under the Curve 166
BL Baseline 167
BT Brachytherapy 168
CBCT Cone beam computed tomography 169
CHT Chemotherapy 170
COP Coverage Probability 171
CR Complete Remission 172
CRF Case Report Form 173
CRT Conformal Radiotherapy 174
CSS Cancer Specific Survival 175
CT Computed Tomography 176
CTCAE Common Terminology Criteria for Adverse Events 177
CTV Clinical Target Volume 178
CuSO4 Copper sulphate 179
D90 The isodose that includes 90% of the target 180
D100 The isodose that includes 100% of the target 181
D2cm3 Minimum dose in the most exposed 2 cm3 of an OAR 182
DFS Disease Free Survival 183
DNA Deoxyribonucleic acid 184
DVH Dose Volume Histogram 185
EANM European Association of Nuclear Medicine 186
EBRT External Beam Radiotherapy 187
EMBRACE The European and International study on MRI-guided Brachytherapy in locally Advanced 188
Cervical Cancer 189
EORTC European Organisation for Research and Treatment of Cancer 190
EPID Electronic Portal Imaging Device 191
ESTRO European Society for Therapeutic Radiology and Oncology 192
EQD2 Equivalent dose in 2 Gy fractions 193
FIGO Fédération Internationale de Gynécologie et d’ Obstétrique 194
FTE Full Time Equivalent 195
Fx Fraction 196
G (Morbidity) Grade 197
GEC Groupe Européen de Curiethérapie 198
GFR Glomerula Filtration rate 199
GI Gastro-Intestinal 200
GTV Gross Tumor Volume 201
Gy Gray 202
HDR High Dose Rate 203
HPV Human Papilloma Virus 204
HR High Risk 205
IC Intracavitary 206
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ICH International Conference on Harmonisation of Technical Requirements for Registration of 207
Pharmaceuticals for Human Use 208
ICRU International Commission on Radiation Units and Measurements 209
IMRT Intensity Modulated Radiotherapy 210
IGRT Image Guided Radiotherapy 211
IR Intermediate Risk 212
IS Interstitial 213
ITV Internal Target Volume 214
IV Intravenous 215
kV Kilovoltage 216
LACC Locally Advanced Cervical Cancer 217
LN Lymph Nodes 218
LR Low Risk 219
MRI Magnetic Resonance Imaging 220
MVCT Megavoltage Computed Tomography 221
N0/N- Lymph Node Negative 222
N1/N+ Lymph Node Positive 223
OAR Organs at Risk 224
OS Overall Survival 225
OTT Overall Treatment Time 226
PAN Para-Aortic Lymph Nodes 227
PDR Pulsed Dose Rate 228
PET-CT Positron Emission Tomography- Computed Tomography 229
PFS Progression Free Survival 230
PI Principal Investigator 231
PIBS Posterior-Inferior Border of Symphysis 232
PTV Planning Target Volume 233
QoL Quality of Life 234
RT Radiotherapy 235
SD Standard Deviation 236
SIB Simultaneous Integrated Boost 237
SPSS Statistical Package for Social Sciences 238
SUVmax Maximum Standardized Uptake Value 239
TNM Tumor (Lymph)Nodes Metastasis 240
TPS Treatment Planning System 241
TRAK Total Reference Air Kerma 242
uCR Uncomplete Remission 243
US Ultrasound 244
VMAT Volumetric Modulated Arc Therapy 245
WHO World Health Organization 246
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2 SUMMARY 248
249
2.1 BACKGROUND 250
The standard treatment of locally advanced cervical cancer is radio-chemotherapy including external beam radiotherapy (EBRT), 251
brachytherapy (BT) and concomitant chemotherapy with weekly Cisplatin. Image Guided Adaptive Brachytherapy (IGABT), with 252
repetitive MRI regarded as gold standard, is increasingly recognized as the new paradigm replacing 2D BT and spreading throughout the 253
world. This spread is at present predominantly in Europe, North America and in many places in Asia. The Gyn GEC ESTRO 254
Recommendations I-IV have been used as the conceptual frame for these developments during the last decade and are now embedded 255
into the new ICRU/GEC ESTRO report 88 which is being published in 2015. 256
Beside increasing mono-institutional clinical experience – also reported in literature – there is increasing clinical evidence and analyses 257
from multi-institutional studies, in particular RetroEMBRACE (n=731) and EMBRACE (n>1350) about dose volume effects and outcome. 258
The mature RetroEMBRACE clinical outcome data and dose volume effect analysis for disease outcome show an improved excellent 259
local and pelvic control and survival and significant dose volume effects for IGABT. Overall treatment time was found to have significant 260
impact on local control, and in addition, volume effects of EBRT were found (IMRT vs. 3D CRT) with impact on morbidity and quality of 261
life. Furthermore, dose effects of chemotherapy (≥5 cycles) were found to have impact on survival in advanced disease. Comprehensive 262
analyses from both large patient cohorts reveal further relevant treatment parameters with major impact on disease outcome, 263
morbidity and quality of life. In the international community the results from the EMBRACE studies are regarded as benchmark for 264
future clinical research in this field. 265
Based on the large success of the RetroEMBRACE and EMBRACE studies, the EMBRACE study and research group decided to continue 266
the clinical research work and to initiate a consecutive EMBRACE II study with interventions derived from the evidence collected within 267
the EMBRACE studies. 268
269
2.2 INTERVENTIONS, AIMS AND HYPOTHESES 270
The EMBRACE II interventions address local, nodal and systemic treatment as well as exposure of organs at risk: 271 272
• Increased use of IC/IS technique in BT 273 • Reduction of vaginal source loading 274 • Systematic utilisation of IMRT 275 • Utilisation of daily IGRT (set-up according to bony structures) 276 • EBRT target concept related to the primary tumour; concepts for OAR contouring 277 • EBRT dose prescription and reporting 278 • Adaptation of EBRT nodal elective CTV according to risk of nodal and systemic recurrence 279 • Systematic application of simultaneous chemotherapy 280 • Reduction of overall treatment time 281 282
The general aims of the EMBRACE II study are: 283 284
To systematically apply IMRT with daily IGRT as well as advanced image guided adaptive BT in a prospective multi-centre 285 setting 286
To systematically implement a dose prescription protocol for IGABT 287
To implement systematic contouring, prescription and reporting for EBRT CTV and OARs. 288
To administer EBRT in different targets which are adapted to the risk of nodal and systemic failure: to improve para-aortic and 289 systemic control in high risk patients and not to decrease lymph node control in low risk and intermediate risk patients 290
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To systematically administer simultaneous chemotherapy to EBRT to reach prescribed dose in as many patients as possible, in 291 particular in high risk patients 292
To benchmark an outstanding high level of local, nodal and systemic control as well as survival with application of advanced 293 EBRT, BT and chemotherapy within limited overall treatment time 294
To benchmark a low incidence of intermediate and major morbidity as well as a high level of quality of life with application of 295 advanced EBRT, BT and chemotherapy 296
297 Beside these general aims, there is a significant number of specific aims which refer to the prospective validation of dose volume 298 parameters from the EMBRACE analyses (e.g. dose escalation for large tumors with increased application of IC/IS techniques), to 299 explore and evaluate dose volume parameters for EBRT and to identify prognostic parameters. 300 301 General and specific hypotheses were formulated for the various interventions (BT, EBRT, chemotherapy) and endpoints (disease, 302 morbidity, quality of life). 303
304
2.3 TYPE OF DESIGN 305
The study is a multicenter prospective interventional study with some areas for observational research (e.g. DVH for IMRT). Reporting 306
on the key patient, tumor, treatment and outcome parameters is mandatory including disease, morbidity and quality of life. Sub-studies 307
as on adaptive IMRT and translational research are optional for cooperation between individual departments. Patient registration and 308
reporting will be performed by the individual investigator via the internet to a central database. 309
310
2.4 PATIENTS TO BE INCLUDED 311
Patients with newly biopsy proven squamous carcinoma, adenocarcinoma or adeno-squamous carcinoma of the uterine cervix, FIGO 312
stage IB, IIA, IIB, IIIA, IIIB and IVA (and nodal status according to TNM) in whom definitive radio-chemotherapy with curative intent is 313
planned are qualified for the study. Treatment has to include IGABT with MRI and IMRT with IGRT and ≥5 cycles of cis-Platin. Patients 314
with para-aortic metastatic nodes (stage IVB) to the level of L2 are also eligible but patients with further dissemination are not (M0). 315
Patient work up and staging includes as a minimum patient characteristics with performance status and blood tests (e.g. haemoglobin, 316
lymphocytes), tumor status (biopsy), gynaecological examination, MRI of the pelvis, abdominal CT or MRI, whole body FDG PET-CT 317
(preferably) or at least chest CT. Further investigations are applied if necessary (e.g. cystoscopy, rectoscopy) or done according to 318
institutional practice (e.g. laparoscopic lymph node assessment). Baseline morbidity scoring and quality of life questionnaire are 319
mandatory. 320
321
2.5 TREATMENT OF PATIENTS IN THE TRIAL 322
All patients will receive both EBRT and concomitant chemotherapy and BT. Summation of EBRT and BT doses will be performed by 323
calculation of a biologically equivalent dose in 2 Gy per fraction (EQD2) using the linear-quadratic model with / = 10 Gy for tumour 324
effects and / = 3 Gy for late normal tissue damage. The repair half time is assumed to be 1.5 hrs. 325
EBRT has to be delivered as IMRT/VMAT with daily cone beam CT (IGRT) in 25 fractions with 1.8 Gy to a total dose of 45 Gy given in 5 326
weeks. Target definition is MRI based (initial GTV) for the CTV-T with an initial HR and LR CTV-T and an ITV-T. CT or MRI based nodal 327
Target (CTV-E) is according to risk of nodal spread “Small Pelvis”, “Large Pelvis” or “Large Pelvis + Para-aortic Region”. Overall CTV/ITV 328
to PTV margin is 5 mm. Involved nodes are boosted preferably based on PET CT with 10-15 Gy and treated as simultaneous integrated 329
boost within 5 weeks (2.2-2.4 Gy per fraction). A range for DVH parameters for the various OARs - contoured according to specific 330
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protocols - is taken into account for treatment planning. The LR CTV-T and the CTV-E will be treated with 45 Gy by use of EBRT (PTV45). 331
Maximal treatment time including both EBRT and BT is 50 days. 332
Brachytherapy is prescribed with dose escalation for advanced disease with large adaptive CTV-THR including IC/IS techniques and dose 333
de-escalation for limited size CTV-THR to spare organs at risk and in particular the upper vagina. The primary imaging method is MRI with 334
the applicator in place which enables definition of the relevant volumes of interest directly on the images for treatment planning: 335
GTVres, adaptive CTVHR, CTVIR and organ volumes. The applicator and the reference points are reconstructed in the same image series. 336
All treatment plans have to be optimized to achieve defined planning aims for dose and volume parameters for tumor (D98 for GTVres) 337
and target volumes (e.g. D90-95 Gy for adaptive CTV-THR) and for 2cm3 reference volumes for OARs (e.g. <80 Gy for bladder, <65 Gy for 338
rectum) and for vaginal reference points (recto-vaginal point < 65 Gy, PIBS). If the planning aims cannot be achieved, limits for the 339
finally prescribed dose levels are defined for GTVres, CTVHR, CTVIR, point A, bladder, rectum, sigmoid bowel and vagina. Planning aim 340
doses and limits for the finally prescribed dose levels are based on the experience of the previous retroEMBRACE and EMBRACE trials. 341
For chemotherapy weekly concomitant Cisplatin (40 mg/m2) for 5-6 courses is standard unless chemotherapy is precluded by patient 342
age, co-morbidity and toxicity. Aim is to apply minimum 5 cycles of cis-Platin, in particular in advanced disease. 343
344
2.6 QUALITY ASSURANCE 345
Only approved departments and investigators can enroll patients into the protocol. This approval is the under the responsibility of the 346
study coordinators. The approved departments are at present those that have contributed continuously to EMBRACE in a considerable 347
number of patients. These departments have to go additionally through a QA procedure for IMRT/IGRT. 348
New departments will have to go through a QA procedure both for IGABT and IMRT/IGRT. Approval requires a compliance 349
questionnaire, successful training, registration and submission of cases and positive evaluation by the study coordinators for each 350
centre. 351
There is no formal on site monitoring, but patient files and treatment plans must be kept at least until closure of the protocol and final 352
analysis of the results is obtained. Continuous data monitoring is performed through the study offices in Vienna and Aarhus and 353
through Utrecht for the centres in the Netherlands. 354
Continuous education will be offered through ACT and annual workshops and EMBRACE meetings. 355
356
2.7 OUTCOME MEASURES 357
Local and nodal (pelvic) control within the specific EBRT and BT targets (HR-CTV-T, IR-CTV, LR CTV-T; CTV-E, CTV-N) and morbidity 358
related to OAR in the pelvis and the para-artic region as well as overall survival, cancer specific survival and systemic control are the 359
primary outcome measures. All endpoints will be evaluated by actuarial statistics. Morbidity will be scored by use of the Common 360
Terminology Criteria for Adverse Events (CTCAE v3.0/4.0). QoL will also be systematically recorded in all patients. 361
362
2.8 EVALUATION OF OUTCOME MEASURES 363
Tumor and nodal remission status (complete, uncertain complete, partial, stable & progressive disease) will be evaluated 3 months 364
after treatment by pelvic (para-aortic, CT) MRI and gynaecological examination. Regular follow-up including gynaecological examination 365
will then be instituted with planned appointments 6, 9, 12, 18, 24, 30, 36, 48 and 60 months after treatment. Pelvic (para-aortic, CT) 366
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MRI will be repeated at 12 months after treatment or in case of suspected recurrence. Morbidity and quality of life will be scored 367
systematically at base line and at each time point during follow-up. 368
369
2.9 SAMPLE SIZE AND DATA MATURITY 370
The study aims at recruiting 1000 patients in 4 years and to follow them for at least 5 years to allow for a meaningful assessment of the 371
endpoints by univariate and multivariate analysis. 372
373
374
375
376
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3 INTRODUCTION 377
378
3.1 BACKGROUND 379
The standard treatment for locally advanced cervical cancer is currently radio-chemotherapy consisting of EBRT, intracavitary BT and 380
concomitant chemotherapy with Cisplatin. During the last decade, the utilisation of MRI guided brachytherapy has grown based on the 381
GEC ESTRO recommendations (Haie-Meder C. et al. 2005, Pötter R. et al. 2006, Hellebust TP. et al. 2010, Dimopoulos JC. et al. 2012) and 382
the cervix is among the first cancer sites where response-adaptive radiotherapy has been successfully implemented in clinical practice. 383
The novel target concepts involved in response-adaptive radiotherapy are described further in section 3.2. Acquisition of MRI at the 384
time of brachytherapy allows the brachytherapy boost to be individually tailored according to the residual tumour volume after 385
typically 40-50 Gy of external beam radiation therapy (EBRT). This approach has changed patterns of clinical practise with regard to 386
dose administration, and significant improvements in clinical outcome have been reported from mono-institutional settings with regard 387
to local control, overall survival and morbidity (Pötter R. et al. 2007, Pötter R. et al. 2011, Lindegaard JC. et al. 2013). 388
In 2008, the GEC-ESTRO Gyn network initiated the “International Study on MRI-Based Brachytherapy in Cervical Cancer” (EMBRACE, 389
www.embracestudy.dk). EMBRACE has recruited >1300 patients by 2015 from 27 international centers performing MRI-guided 390
brachytherapy. The purpose of the EMBRACE study is to evaluate and benchmark MRI-guided brachytherapy in a prospective 391
multicenter study. In 2010, the GEC-ESTRO Gyn network also initiated the retrospective study retroEMBRACE, in which 852 patients 392
treated with image-guided brachytherapy prior to initiation of EMBRACE accrual have been included to provide long-term outcome 393
data for image-guided brachytherapy while the EMBRACE study data is still maturing (www.retroembrace.com). 394
Data from retroEMBRACE shows that overall local control is excellent with 89% at 5 years with 98% in stage IB and 91% in IIB tumours. 395
However, in stage IIIB tumours there is still a significant challenge with regard to local control which is 75% at 5 years (Sturdza A. et al. 396
in submission 2015). Nodal and systemic control also remains challenging with levels of 87% and 77% at 5 years, respectively (all stages) 397
(RetroEMBRACE 01/2015 work in progress). Furthermore, treatment related urinary and gastrointestinal late morbidity is still a 398
significant problem with the 3 year actuarial incidence of intermediate to major morbidity (G≥2) being 30% and 29% for urinary and 399
gastrointestinal side effects, respectively, according to EMBRACE data. Major morbidity (G≥3) is seen in 7% and 8%, respectively 400
(EMBRACE 2014, work in progress). Patient reported symptoms are equally high with 30-40% of patients reporting significant urinary 401
and gastrointestinal bother according to quality of life data from the EMBRACE study (EMBRACE 2015, work in progress). Sexual side 402
effects are still poorly understood although almost 30% of patients develop significant narrowing and shortening of the vagina 403
(Kirchheiner K. et al. 2014). Further development of both BT and EBRT is needed to improve on local control, regional control as well as 404
on treatment related morbidity and quality of Life. 405
Adjuvant and neo-adjuvant chemotherapy has been proposed to improve systemic control, and is currently being evaluated in a 406
randomized phase III study (OUTBACK, https://www.rtog.org/ClinicalTrials/ProtocolTable/StudyDetails.aspx?study=1174; INTERLACE 407
www.cancerresearchuk.org). However, local and nodal disease also has impact on systemic disease, and therefore improvement on 408
loco-regional treatment is equally important. Recent developments in advanced image guidance for both EBRT and BT have potential to 409
improve local as well as nodal and also systemic control. Furthermore, the new technologies has potential to decrease organ doses as 410
well as well as the overall burden of treatment, with the promise to significantly reduce treatment related organ symptoms and overall 411
quality of life. 412
Advances in image guided adaptive brachytherapy include improved individualisation of brachytherapy applicators as well as 413
individualised dose optimisation. Dose optimisation using intracavitary (IC) applicators has shown to significantly decrease OAR dose 414
and morbidity (Charra-Brunaud C. et al. 2012). Dose optimisation based on IC may be used to improve target dose coverage in tumours 415
of limited size at BT, but for large residual tumours or in case of unfavourable topography, IC BT has limited possibilities to cover the 416
CTVHR to doses larger than e.g. 85Gy (Tanderup K. et al. 2010). Combined intracavitary-interstitial (IC/IS) applicators have been 417
developed for targeting tumours which are not well covered by intracavitary (IC) applicators (Dimopoulos JC. et al. 2006, Kirisits C. et al. 418
2006). The IC/IS applicators allow for improved dose conformality, and target dose escalation and/or dose de-escalation in organs at 419
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risk can be carried out (Fokdal L. et al. 2013). Furthermore, in the process of moving from standard loading to 3D image guided 420
optimisation there has so far been reluctance to change the loading drastically in ovoids and ring, in order to stay as close as possible to 421
previous clinical practise. However, EMBRACE data have demonstrated that dose to the ICRU recto-vaginal point correlate with the 422
probability of G≥2 vaginal morbidity (Kirchheiner K. et al. in submission 2015). This observation is a strong motivation to explore new 423
approaches to dose optimisation which spare vaginal mucosa and decreases the dose to the ICRU recto-vaginal point. 424
Pelvic EBRT is currently delivered with different techniques: 3D conformal EBRT, intensity modulated radiotherapy (IMRT), volumetric 425
arc techniques (VMAT), and tomotherapy. Application of IMRT in cervix cancer significantly reduces the volume of tissue irradiated to 426
intermediate doses such as 30-40Gy for bladder, rectum, sigmoid and bowel (Forrest J. et al. 2012). The progress from 3D conformal 427
EBRT to IMRT has demonstrated a reduction of treatment related morbidity in mono-institutional and retrospective settings (Mundt AJ. 428
et al. 2003, Xu KM. et al. 2015). Furthermore, EMBRACE quality of life data has shown a significantly lower incidence of bowel 429
symptoms in patients treated with IMRT as compared to 3D conformal EBRT with the four-field box technique (see Figure 3.6 and 3.7). 430
During the last decade, a variety of techniques, such as kV x-ray, cone beam CT (CBCT) or megavolt CT (MVCT), have been developed to 431
improve the possibilities to perform on board image guidance in EBRT. With imaging devices mounted on or in a fixed relationship to 432
the accelerator, it is now possible to perform daily imaging with the patient in the treatment position. The on-board images can be 433
fused with the treatment planning scan and a couch correction can be applied to correct for translational setup errors. In the case of 434
cervix cancer the daily imaging can be used for visualisation and fusion of bony anatomy. By using daily image guided set-up in cervix 435
cancer, the precision of the elective lymph node clinical target volume (CTV-E) can be significantly improved (Laursen LV. et al. 2012), 436
and thereby planning target volume (PTV45 Gy) margins can be reduced. A further step is to use daily image guidance (CBCT) to 437
visualise soft tissue such as bladder and uterus in order to further reduce the PTV-T margins which are applied to take into account the 438
motion of the primary gross tumour volume (GTV), the CTV-T and the uterus (see chapter 9). Such approaches have been developed 439
and involve adaptive EBRT where daily library plans are applied (Heijkoop ST. et al. 2014). Decrease of PTV margins as well as 440
implementation of IMRT has potential to reduce morbidity, in particular bowel morbidity. 441
The primary aim of EMBRACE II is to implement a risk adaptive dose prescription protocol in locally advanced cervical cancer. The 442
individualised dose prescription is based on evidence of dose and effect relationships for target and OARs from the EMBRACE and 443
retroEMBRACE studies and involves a set of new dose planning aims. The ability to reach these dose planning aims is based on 444
interventions in terms of advanced BT and EBRT technology. Advanced BT involves increased utilisation of IC/IS applicators as well as 445
vaginal dose de-escalation. Advanced EBRT involves IMRT as well as daily image guidance utilising margin reduction. This approach will 446
enable delivery of increased focal doses to gross disease (primary tumour and positive lymph nodes) as well as reduction of high and 447
intermediate dose to OARs. The improved dose administration is hypothesised to benchmark an outstanding high level of local, nodal 448
control, and systemic control as well as a low incidence of intermediate and major morbidity. Through this well-controlled prospective 449
interventional study we aim to achieve the composite aims listed in section 4.2. 450
3.2 TUMOR AND TARGET CONCEPTS FOR RESPONSE ADAPTED RADIOTHERAPY IN CERVIX CANCER: 451
RESIDUAL GTV-T, ADAPTIVE CTV-THR AND CTV-T IR 452
The target concept for response-adapted radiotherapy is focussed on the primary tumour change (GTV-T) and the change of the CTV-T 453
during upfront chemo-radiation. These changes are essential for selecting the appropriate target for brachytherapy (see chapter 5.4, 454
ICRU report 88). Therefore new terms and concepts have been introduced as compared to ICRU 50, 62 and 83 which correspond to 455
those of the Gyn GEC ESTRO Recommendations I and II (Haie-Meder C. et al. 2005, Pötter R. et al. 2006). These terms and concepts are 456
further elaborated in the ICRU/GEC ESTRO report 88. Therefore, in the following, a short summary is given, taken from the recent 457
ICRU/GEC ESTRO report 88 (chapter 5): 458
“Residual GTV-T (GTV-Tres) is defined as the residual macroscopic tumor at the time of (brachytherapy) boost after treatment assumed 459
sufficient to control microscopic disease. GTV-Tres still bears clinical and/or imaging characteristics similar to the initial GTV-Tinit and may 460
represent macroscopic and/or microscopic and/or even no residual disease. 461
14
Residual pathologic tissue may surround the residual GTV-T and bears different clinical and/or imaging characteristics (e.g. edema, 462
fibrosis) compared to the initial GTV-T. It is always located within the region of the initial GTV-T. 463
Adaptive CTV-T (CTV-Tadapt) can be defined after any treatment phase and includes in any case the GTV-Tres and the residual 464
surrounding pathologic tissue, if present. The adaptive CTV-T is a sub-volume of the initial CTV-T, except in case of tumor progression. 465
Adaptive High Risk CTV-T (CTV-T HRadapt) is defined as a specific form of the adaptive CTV-T for cervix cancer radiotherapy following the 466
GEC ESTRO recommendations. CTV-T HRadapt includes the GTV-Tres and the whole cervix and adjacent residual pathologic tissue, if 467
present. It is the volume bearing the highest risk for recurrence. The CTV-T HRadapt for cervix cancer is selected by clinical examination 468
and imaging at the time of brachytherapy, after 40-45 Gy EBRT plus chemotherapy in advanced cervical cancer.* 469
Intermediate Risk CTV-T (CTV-T IR) represents the area of the GTVinit as superimposed on the topography at the time of brachytherapy 470
and a margin surrounding the anatomical cervix borders (CTV-T HRadapt) in areas without an initial GTV-T. The CTV-T IR therefore always 471
includes the CTV-T HRadapt and margins as appropriate. 472
Adaptive Low Risk CTV-T (CTV-T LRadapt) represents compartmental areas at risk for potential contiguous or incontiguous microscopic 473
spread from the primary tumor. CTV-T LRadapt comprises in advanced cervix cancer the whole parametria, the whole uterus, the upper 474
part of the vagina and the anterior/posterior spaces towards bladder and rectum. This CTV-T LR always includes the CTV HR/IR, 475
respectively. The CTV-T LR is defined at diagnosis (initial CTV-T LR) and maybe adapted during EBRT and also at brachytherapy (adaptive 476
CTV-T LR).*” (ICRU 88, 2015) 477
* in EMBRACE II an initial CTV-T HR (CTV-T HRinit) and an initial CTV-T LR (CTV-T LRinit) are defined for EBRT which correspond to the 478
adaptive CTV-Ts as defined for brachytherapy (see chapter 9). 479
Examples, variations and uncertainties for selection and contouring of the initial and residual GTV-T and the initial and adaptive CTV-T 480
are described in detail in ICRU 88, in chapter 9 and 10, and in the appendix. Most research work has focussed so far on the adaptive 481
CTV-T. Uncertainties vary with method of investigation (e.g. imaging modality such as MRI, CT, US) with MRI and clinical examination at 482
present regarded as gold standard. For this reason, MRI and clinical examination are mandatory tools for EMBRACE II at diagnosis and 483
during treatment, in particular at the time of brachytherapy. 484
In the following, typical examples for contouring are given for brachytherapy in schematic diagrams for contouring of GTV-Tres, adaptive 485
CTV-T HR, CTV-T IR and adaptive CTV-T LR taking into account various disease extensions and stages at diagnosis and various forms of 486
response (taken from ICRU report 88). The 9 comprehensive examples in the Appendix of ICRU 88 are also of major interest. 487
488
15
489
Figure 3.1 (compare figure 9.4 for EBRT). “Schematic diagram for cervical cancer, limited disease, stage IB1, with initial GTV-T, initial 490
CTV-THR (cervix) and initial CTV-TIR (margins around cervix)* and initial CTV-TLR (margins for whole parametria, whole uterine corpus, 491
upper third of vagina, utero-bladder and cervix-rectum space) for initial brachytherapy combined with EBRT: coronal, transversal and 492
sagittal view (see also Appendix example 1, Paris)” (Fig. 5.8 from ICRU report 88 in press). *only considered for brachytherapy in 493
EMBRACE II. 494
495
Figure 3.2 (compare figure 9.5 for EBRT). “Schematic diagram for cervical cancer, stage IB2 (bulky disease), good response after chemo-496
radiotherapy: residual GTV-T (GTV-Tres), adaptive CTV-T HR (CTV-T HRadapt), initial GTV-T (GTV-Tinit), intermediate risk CTV-T (CTV-T IR) 497
(GTV-T init plus margins around the CTV-T HRadapt) and CTV-T LRadapt for adaptive brachytherapy: coronal, transversal and sagittal view 498
(see also Appendix example 2)” (figure 5.9 from ICRU report 88 in press). 499
16
500
Figure 3.3 (Compare figure 9.6 for EBRT) “Schematic diagram for cervical cancer, stage IIB bulky disease and good response after 501
chemo-radiotherapy: GTV-Tinit, GTV-Tres and extra-cervical gray zones, adaptive CTV-T HR, CTV-T IR (GTV-Tinit plus margins around the 502
CTV-T HR ) and CTV-T LR for adaptive brachytherapy: coronal, transversal and sagittal view. Maximum width, thickness and height of 503
the adaptive CTV-T HR are indicated (see also example 5 in the Appendix)” (figure 5.10 from ICRU report 88 in press). 504
505
Figure 3.4 (compare figure 9.7 for EBRT). “Schematic diagram for cervical cancer, IIIB, extensive disease, poor response after chemo-506
radiotherapy: large initial and residual GTV-T (GTV-Tinit, GTV-Tres), extensive gray zones, adaptive CTV-T HR, CTV-T IR (GTV-Tinit plus 507
margins around the CTV-T HR) and CTV-T LR for definitive treatment: coronal and transversal view. Maximum width, thickness and 508
height of the CTV-T HR are indicated (see also examples 6 and 8 in the Appendix)” (figure 5.11 from ICRU report 88 in press). 509
17
510
Figure 3.5 (compare figure 9.8 for EBRT). “Schematic diagram for cervical cancer, with bladder infiltration, stage IVA, and good response 511
after chemo-radiotherapy: large initial and residual GTV-T (GTV-Tinit, GTV-Tres), extensive gray zones, residual infiltration in the posterior 512
bladder wall; adaptive CTV-T HR, CTV-T IR (GTV-Tinit plus margins around the CTV-T HR), CTV-T LR for adaptive brachytherapy: coronal, 513
transversal and sagittal view. Maximum width, thickness and height of the HR CTV-T are indicated.” (figure 5.12 from ICRU report 88). 514
515
3.3 EVIDENCE FROM THE RETROEMBRACE AND EMBRACE STUDIES 516
When the prospective EMBRACE study was designed, there was still only limited evidence on dose and effect relations for target or 517
organs at risk (OAR), and it was not yet time to aim for a specific dose prescription for the target or specific dose constraints for organs 518
at risk (OAR). Therefore, brachytherapy dose prescription in the EMBRACE study was based on institutional practice which varied 519
considerably with regard to total dose, fractionation, dose rate, and brachytherapy applicators. This means that a significant variation in 520
dose prescription is present both at the institutional as well as on the patient level in the retroEMBRACE and EMBRACE studies. This 521
heterogeneity in dose administration has provided a unique opportunity to learn about the effect of different dose levels, and a vast 522
amount of new knowledge on dose and effect relationships is currently growing from the EMBRACE and retroEMBRACE studies for 523
GTVres, CTVHR, CTVIR, bladder, rectum, bowel, and vagina. Furthermore, there are a number of mono-institutional studies on dose and 524
effect, in particular on rectum and CTVHR (Georg P. et al. 2012, Koom WS. et al. 2007). The new knowledge from EMBRACE as well as 525
published literature on dose and effect is the prerequisite of designing the EMBRACE II dose prescription protocol with dose planning 526
aims for target and OARs. In the following sections the upcoming dose effect data from retroEMBRACE and EMBRACE is described. 527
3.3.1 LOCAL CONTROL AND D90 TO CTVHR, GTV AND CTV IR 528
Relation between target dose (CTVHR, GTV and CTVIR) and incidence of local control was analyzed in a clinical material of 488 pts 529
enrolled in the retroEMBRACE study from 6 institutions performing MRI guided adaptive brachytherapy. A significant dose effect 530
relationship was found for CTVHR, GTV and CTVIR in stage II and stage III disease (figure 3.6). Furthermore, for HR CTV a cox regression 531
dose response analysis showed that both CTVHR volume and dose was related with local control. The data supports a dose constraint of 532
≥85Gy EQD2 to the CTVHR D90 which is predicted to lead to a 3-year actuarial local control of >96% in tumours ≤30cc and >91% in 533
tumours >30cc. Dose planning aims for CTVIR and GTVres proposed for similar levels of local control are: CTVIR D98≥60Gy and GTVres 534
D98≥95Gy. 535
18
Utilization of combined intracavitary/interstitial (IC/IS) applicators is an essential tool for dose escalation in large tumours. In terms of 536
dose, the IC/IS applicators can widen the therapeutic window by 5-10Gy as demonstrated by direct comparison between IC and IC/IS 537
applicators (Fokdal L. et al. 2013). This is further supported by data from the retroEMBRACE and EMBRACE studies which demonstrate 538
that application of IC/IS in a significant proportion of the patients (>20-50%) is essential for reaching a high dose to CTVHR (>85Gy) in the 539
majority of patients. In retroEMBRACE, the CTVHR dose administration was larger by 10Gy in institutions systematically applying 540
combined IC/IS applicators, while doses to OARs were not increased. The increased dose resulted in improved local control in patient 541
cohorts where application of IC/IS was performed in at least 20% of the patients (figure 3.7). Since the target dose escalation did not 542
involve significant increase of dose to OARs, the incidence of morbidity was not different in the patient cohort with frequent application 543
of IC/IS as compared to the cohort where mainly IC was applied, although there was a tendency that vaginal morbidity was slightly 544
increased in the IC/IS cohort. 545
Figure 3.6. Dose response in stage II and stage III for adaptive CTV-THR, GTV-Tres and CTV-TIR. (Tanderup K. et al. in submission 2015) 546
547
19
548
CTVHR ≥ 30 cm3
CTVHR < 30 cm3
gure 3.7. Local control for large (left panel) and small (right panel) CTVHR, as depending on routine application of IC/IS technique. 549
Advanced adaptive brachytherapy implies that >20% of the patients in the cohort were treated with IC/IS. Limited adaptive 550
brachytherapy implies that the majority of patients (<20%) were treated with IC technique. Data from retroEMBRACE (Fokdal L. et al. 551
2015, RetroEMBRACE work in progress). 552
553
3.3.2 OVERALL TREATMENT TIME 554
The effect of overall treatment (OTT) time was investigated in the same clinical material as in section 3.2.1: 488 pts enrolled 555
in the retroEMBRACE study from 7 institutions. Multivariate Cox Proportional Hazards modelling was performed to include 556
the effects of stage, histology, CTVHR dose, CTVHR volume, and OTT. The effect of OTT shortening by one week was 557
equivalent to escalating CTVHR dose by 5Gy (D90), resulting in increase of local control by 1.0% for CTVHR volume of 558
20cm3, 1.2% for 30cm3, and 2.5% for 70cm3. The dose constraints and levels of local control introduced in 3.2.1 are valid 559
for a treatment time of 7 weeks, and therefore if treatment time is longer or shorter than 7 weeks, the dose planning aims 560
should in principle be adjusted by 5Gy per week for CTVHR. The data underlines the importance of keeping the OTT as 561
short as possible, in particular for large size CTVHR, where higher dose is needed to reach >90% local control. 562
563
3.3.3 URINARY MORBIDITY AND BLADDER D2CM3 564
A clinical material of 680 pts from EMBRACE was analysed. A total number of 95 events of ≥G2 morbidity occurred (ureter stenosis 565
excluded). The dominating events were frequency, urgency and cystitis. A significant dose relationship was present which indicates that 566
at dose levels beyond 80Gy EQD2 there is a clinically significant increase in ≥G2 morbidity (figure 3.8) (Tanderup K. et al. 2014, 567
EMBRACE work in progress). 568
The location of the D2cm3 has shown to be of significance for development of urinary morbidity, which has been shown by using the ratio 569
between D2cm3 and ICRU bladder dose as a surrogate of the D2cm3 location (Nkiwane KS. et al. 2015, Mazeron R. et al. 2015). 570
20
Figure 3.8. Actuarial incidence of G≥2 urinary
morbidity (all endpoints except ureter stenosis)
grouped according to D2cm3 dose levels
(Tanderup K. et al. 2014, EMBRACE work in
progress).
3.3.4 RECTAL BLEEDING AND RECTUM D2CM3 571
A clinical material of 701 patients from EMBRACE was analysed. Rectal bleeding (50 events) correlated significantly with dose (figure 572
3.9). The dose response was shallow below 70Gy, and it is unclear how much clinical impact dose de-escalation below 70Gy could have. 573
However, for doses above 70-75Gy there is a steep increase in risk of rectal bleeding. Analysis of further endpoints such as bowel 574
control is pending. 575
Figure 3.9. Actuarial incidence of rectal bleeding
grouped according to D2cm3 dose levels (Mazeron R.
et al. in submission 2015)
3.3.5 BOWEL MORBIDITY AND SIGMOID/BOWEL D2CM3 576
In the EMBRACE material (701 pts) it was not possible to identify any significant relation between D2cm3 sigmoid and bowel dose and 577
morbidity related to these organs. However, D2cm3 assessment in sigmoid and bowel is highly uncertain due to mobility of these organs. 578
EMBRACE does not have any information recorded about the mobility of bowel/sigmoid in between BT fractions, and the EMBRACE 579
data may therefore not be able to reveal any underlying dose response effect. In particular, if adhesions are present, the organ 580
movement will not degrade the dose, and there may be a significant clinical effect of D2cm3 in such cases. Based on an assumption that 581
sigmoid and bowel are more radiosensitive organs than rectum, doses of 60-70Gy may have an effect, in case of adherences. 582
Furthermore, in EMBRACE there were only few patients where sigmoid or bowel D2cm3 exceeded 75Gy (7% and 10% of the patients, 583
respectively), and any dose effect beyond such dose levels cannot be revealed with EMBRACE data. Therefore, although no dose 584
21
response could be assessed in EMBRACE, it may be appropriate to aim for sigmoid and bowel dose planning aim of 70Gy in case there 585
are adherences. 586
3.3.6 VAGINAL MORBIDITY AND ICRU RECTO-VAGINAL DOSE 587
Vaginal morbidity has been analysed in 754 pts in the EMBRACE material. The majority of ≥G2 events were vaginal stenosis (140 out of 588
181 events) which occurred mainly within the first 18 months. In a patient population of 630 pts a more detailed dose effect analysis 589
was carried out. There was a significant correlation between incidence of vaginal stenosis and the dose to the ICRU recto-vaginal point. 590
At a dose level of 65Gy the incidence of vaginal stenosis was 20% and this increased to 27% at a dose of 75Gy (figure 3.10). 591
Furthermore, there was a significant impact of EBRT dose. With lower dose (≤45Gy), the 2-year actuarial probability was 17% vs. 30% 592
with higher dose. 593
Figure 3.10. Dose effect curve based on Cox regression model
of dose to the ICRU recto-vaginal point in total EBRT+BT EQD2
and vaginal shortening/narrowing G≥2. The model represents
actuarial probability at 2 years (Kirchheiner K. et al. in
submission 2015).
594
3.3.7 GASTROINTESTINAL/URINARY MORBIDITY AND INTERMEDIATE DOSE LEVELS RELATED TO EBRT 595
A number of 387 pts with >12 months of follow up were analysed. The influence of intermediate dose levels on development of GI and 596
urinary morbidity (patient reported EORTC QoL) was investigated through parameters related to EBRT: technique (IMRT/CRT) and 597
irradiated volume (43Gy and 57Gy). There was a significant relation between EBRT technique and GI and urinary patient reported 598
symptoms (”quite a bit” and ”very much”). Furthermore, a relation was found between the total body (abdominal) volume which was 599
irradiated to >43Gy and the incidence of diarrhea (figure 3.11). With an increase in volume from 2000cm3 to 3000cm3 there was an 600
increase in diarrhea from 12% to 22%. This increase is rather shallow and likely related to the fact that the total irradiated body 601
(abdominal) volume is only a limited surrogate for the volume of bowel irradiated. 602
Furthermore, preliminary EMBRACE analyses indicate that there is a tendency that IMRT reduces late bowel morbidity compared to 3D 603
conformal EBRT (e.g. diarrhea) (figure 3.12). 604
605
22
Figure 3.11. Crude incidence of diarrhea
(patient reported) according to body
(abdominal) volume irradiated to >43 Gy
(Tanderup K., Kirchheiner K. 2014, EMBRACE,
work in progress).
Figure 3.12. Prevalence at 18 months after
treatment of patient reported outcome on the
question « have you had diarrhea?» comparing
IMRT and 3D conformal EBRT (Kirchheiner K. et
al. 2014, EMBRACE work in progress).
606
3.3.8 PATTERNS OF SPREAD AND PROGNOSTIC PARAMETERS FOR NODAL PELVIC AND PARA-AORTIC 607
RECURRENCES 608
In EMBRACE, 47 % of the patients had nodal metastases at time of diagnoses, either verified with surgical approaches or with imaging 609
(CT, MRI or PET-CT). A preliminary analysis of nodal recurrences in 816 patients in EMBRACE showed that nodal disease at time of 610
diagnoses was mainly located in the pelvis (internal/external iliac including obturator and common iliac region) while nodal recurrences 611
after treatment was predominantly seen in para-aortic nodes (see Figure 3.13). Para-aortic failures contributed with 69% of all nodal 612
failures with the strongest predictor being nodal disease at time of diagnosis. In total, 62 para-aortic failures occurred. In 406 N+ 613
23
patients at diagnosis there were 47 para-aortic failures (11.5%) and 15 (3.7%) para-aortic failures were seen in the N- group of 410 614
patients. 78% of para-aortic failures in EMBRACE were in patients who did not receive para-aortic irradiation. 615
Recently published data for node positive cervix cancer patients show promising results after extended field IMRT, not to the cost of 616
treatment related morbidity. The PAN control reported is 95 % in case of PAO negative and 89% in case of PAO positive patients at time 617
of diagnosis (Vargo JA. et al. 2014). Based on these results it is likely that increasing the rate of elective PAN irradiation in patients with 618
nodal disease at time of diagnosis will help increasing tumor control in the para-aortic region. Therefore, PAN irradiation will be further 619
investigated in EMBRACE II with special focus on in the group of patients with high risk features for the development of PAN and distant 620
disease which seem to be mainly location of nodes (common iliac), number of nodes (≥3) and also to some degree nodal size (Nomden 621
C., Fortin I. et al. EMBRACE work in progress). 622
In an analysis of 304 lymph node negative patients from the EMBRACE cohort, a low risk group for nodal recurrence could be identified 623
with the following features: Stage IB1, IA, IIA1; Tumour diameter ≤4cm, no uterine involvement and squamous cell cancer. In this low 624
risk group 1/71=1.4% nodal failures (pelvic and para-aortic) were identified. 625
Figure 3.13. Patterns of spread for lymph node disease
at time of diagnosis (left panel) and at time of first nodal
failure (right panel) (Nomden C. et al. EMBRACE work in
progress).
Nodal SUVmax seems to be predictive of nodal control and disease recurrence (Kidd EA. et al. 2010) in pelvic lymph nodes. They 626
measured the SUVmax of the most FDG avid lymph node in 83 node positive patients. No nodal boost was delivered. The average nodal 627
SUVmax was 6.9 (range 2.1-33.0), the average tumour SUVmax was 14.0 (2.1-38.4). They found a weak correlation between nodal size and 628
SUVmax and between nodal and primary tumour SUVmax. Patients with a nodal SUVmax > 4.3 had a lower OS, DFS and pelvic control. They 629
also had a higher risk of nodal persistent disease suggesting that these nodes might have benefitted from a more aggressive treatment. 630
Onal et al. investigated 93 patients with PET-positive pelvic or para-aortic lymph nodes. SUVmax was measured for the most FDG avid 631
node. A sequential boost was delivered for all enlarged lymph nodes. The mean SUVmax for pelvic nodes, para-aortic nodes and primary 632
tumour was 8.4 (+/- 4.3), 6.7 (+/- 2.8) and 19.7 (+/- 8.0) respectively. A strong correlation was found between nodal size and nodal 633
SUVmax and between nodal and primary tumour SUVmax. Patients with pelvic nodal SUVmax > 7.5 had significantly larger nodes and 634
higher SUVmax for both primary tumour and para-aortic nodes. Ten patients had nodal recurrence. 9/10 recurred within the high SUVmax 635
nodal region. Patients with higher SUVmax had lower DFS and OS (Onal C. et al. 2015). 636
Finally a recent study by Ramlov et al. investigated 139 patients. Of these 112 had a diagnostic PET or PET/CT performed. Seventy-five 637
patients had totally 209 nodes treated with chemo-radiotherapy and a nodal boost. Total nodal dose, nodal volume and nodal SUVmax 638
were determined. SUVmax was determined for all PET-positive nodes and not just the most FDG avid node. Six out of 209 boosted nodes 639
recurred. No impact of nodal volume or nodal dose was found for the risk of nodal recurrence. The median SUVmax for all nodes was 5.5 640
24
(range 2-21) and 11 (range 4-16) for the six recurrent nodes. Nodal SUVmax was significantly higher for the recurrent nodes (p= 0.02). 641
The relation between nodal dose/nodal volume and nodal dose/nodal SUVmax are presented in figure 3.14 (Ramlov A. et al. 2015). 642
643
Figure 3.14. Nodal recurrences as depending on dose and volume (left panel) and SUV and dose (right panel) (Ramlov A. et al. 2015). 644
3.3.9 ADMINISTRATION OF CHEMOTHERAPY 645
The advantage of chemoradiation over radiotherapy alone has been well documented with several randomized studies over the last 646
decades. Overall survival and event free survival benefit were confirmed in meta-analysis as well. Several platinum based 647
chemotherapy and non-platinum schedule or regimen were studied, but there is insufficient evidence suggesting that a specific 648
regimen/schedule is superior. 649
However the total number of cycles received during the treatment seems to play an important role in the systemic control in high risk 650
patients (Schmid MR. et al. 2014). An early analysis from EMBRACE study performed on 753 patients shows significantly more systemic 651
relapses in the N+ and advanced stage patients who received 4 chemotherapy cycles and less in comparison with the patients who 652
received 5 chemotherapy cycles or more (Figure 3.14). At 24 months, N+ and advanced FIGO stage patients show a systemic control of 653
63% vs 88% in patients having received 4 cycles and less versus 5 cycles and more, respectively. At 3 and 5 years, the distant 654
metastases free interval was 79% and 77%, respectively in the whole cohort. These results are in line with those of Schmid et al. 2014 655
in that the administration of 5–6 full dose cycles of chemotherapy can reduce a patient's risk of developing distant metastasis, 656
especially in patients showing more advanced disease characteristics such as N+ and advanced FIGO stage. 657
658
659
Figure 3.14. Impact of number of chemotherapy cylcles on systemic control. Advanced stage is defined as stage III and IV (Fortin I. et al. 660
Abstract ASTRO 2015, EMBRACE work in progress). 661
25
3.4 INTERNAL TARGET MOTION 662
The use of more conformal inverse planning techniques (IMRT, VMAT, tomotherapy) has raised the importance of the internal target 663
motion during the course of fractionated EBRT. Besides filling status of surrounding bladder and bowel structures, both tumour 664
extension at diagnosis and tumour regression during treatment have impact on internal target motion. Several studies have 665
documented the distances and directions of movement of the cervix and uterus in relation to organ filling on serial CT, MRI, or CBCT 666
imaging, while other studies primarily described the necessary standard CTV to PTV margins for 95% CTV coverage. Importantly the 667
majority of these studies did not use a protocol for bladder or bowel filling. 668
Main general findings are that the motion is patient specific and that the motion of the uterus (excluding the cervix) is greater than that 669
of the cervix and these can move in independent directions. The greatest motions are observed in the anterior-posterior direction 670
followed by superior-inferior directions. Bladder filling status seems to impact more on the uterine motion and rectal filling more on the 671
motion of the cervix and upper vagina. A systematic review of organ motion in cervix cancer summarises studies on uterine and cervix 672
movements (Jadon R. et al. 2014). For the cervix, the reported mean movement ranges in the anterior-posterior direction between 2-21 673
mm, with standard deviations ranging between 3.5-10 mm; superior-inferior 2-16 (SD range 3-8 mm); lateral 0-10 mm (SD range 1-7 674
mm). For the uterine part corresponding figures are anterior-posterior 4-14 mm (SD range 9-12 mm); superior-inferior 2-10 (SD range 7-675
12 mm); lateral 0-7 mm (SD range 1-8 mm). Observed maximal movements could be up to 4-6 cm again mainly in the anterior-posterior 676
and superior-inferior directions. Different studies report a decrease of mean bladder volume during the course of fractionated 677
radiotherapy, while this was not found for rectal volume. There are few studies that have looked at motion of lymph node related 678
target structures, a study using MRI found mean motions ranging between 5 and 9 mm, while movement of regional vessels was 679
correlated to bladder filling status. 680
The major shortcoming in the field is that the majority of research on motion has focussed on quantifying the magnitude of the 681
movement in mm or has reported dose coverage. The direct impact of motion on dose has so far only been reported in three studies. 682
Lim et al showed that a 15 mm GTV to PTV margin covered always the GTV to > 98% of prescribed dose (20 patients) (Lim K. et al. 683
2009). Jensen et al showed that accumulated EBRT D98 to the uterus was >42Gy in 9/10 and 38Gy in 1/10 patients with a 15mm margin 684
from uterus to PTV (Jensen NBK. et al. 2015). Evaluating accumulated EBRT and BT uterus D98, it was always >45Gy. These two studies 685
indicate that even if the CTV is outside the PTV in a significant number of fractions, the impact on accumulated dose is limited due to 686
shallow dose gradients. Furthermore, Assenholt et al. showed that application of a PTV margin of 5mm on pathological lymph nodes 687
boosted with SIB technique resulted always in D98 > 95% accumulated dose (40 lymph nodes) (Assenholt M. et al. Abstract BigART 688
2015). 689
690
26
4 INTERVENTIONS AND AIMS 691
4.1 INTERVENTIONS 692
Based on the evidence for dose effects from the EMBRACE and retroEMBRACE studies there is a clear evidence based rationale to 693
implement an overall dose prescription protocol based on a set of dose planning aims and dose constraints for the target related to 694
the primary tumour (CTV-T) and the 2cm3 and reference points for OARs (see chapter 10.8). The fulfillment of these planning aims is 695
hypothesized to result in improved local control and decreased morbidity. 696
The ability to reach these planning aims and dose constraints relies on a change of practice for both EBRT and BT dose administration as 697
compared to current practice in the EMBRACE study. The change of practice involves a number of interventions in terms of systematic 698
utilization of advanced image guided BT and EBRT: advanced BT involves increased use of IC/IS and vaginal dose de-escalation, and 699
advanced EBRT involves application of IMRT and IGRT. 700
Furthermore, the current pattern of spread for nodal recurrences as found in EMBRACE will be addressed by treating patients at high 701
risk of nodal and systemic recurrence with para-aortic irradiation and patients with a low risk with small pelvis radiotherapy. Patients 702
with an intermediate risk will receive a large pelvis elective nodal target. 703
4.1.1 INCREASED USE OF IC/IS TECHNIQUE IN BT 704
In EMBRACE, half of the patients have been treated in institutions performing mainly IC brachytherapy (“IC centers”), where IC/IS was 705
carried out in ≤20% of the patients. The other half of the patients have been treated in institutions with routine application of IC/IS (“IC 706
+ IC/IS centers”). The dose administration in the “IC” and “IC + IC/IS” cohorts differs significantly (table 4.1). In centers performing IC + 707
IC/IS the dose to CTVHR was >85Gy for 83% of the patients, whereas this was obtained in 48% of the patients from IC centres. 708
Furthermore, 24% of the patients received >95Gy to the CTVHR - predominantly in small volume CTVHR and in centres using IC/IS in a 709
high percentage of patients. 710
In most centers routinely applying IC/IS, the rate of application is normally much higher than 20% (table 4.1), since application of IC/IS 711
can also benefit OAR sparing. 712
Adaptation HR CTV vol Applicatio
n of IC/IS
HR CTV D90 Bladder
D2cm3
ICRU recto-
vag. dose
Rectum
D2cm3
IC* <30cc 7% 87±9Gy 73±11Gy 68±12Gy 62±8Gy
IC + IC/IS** <30cc 34% 94±11Gy 75±13Gy 65±10Gy 62±9Gy
p-value <0.001 <0.001 <0.001 0.807
IC*
>30cc
25%
80±11Gy
81±12Gy
74±16Gy
66±12Gy
IC + IC/IS** >30cc 75% 88±7Gy 79±10Gy 68±9Gy 65±7Gy
p-value <0.001 0.101 <0.001 0.087
*Centers applying IC/IS in ≤20% of the patients; **Centers applying IC/IS in >20% of the patients 713
Table 4.1. Practice of dose administration in EMBRACE (Tanderup K. et al. 2015, EMBRACE work in progress) 714
27
In EMBRACE II, the improved therapeutic window (through increased application of IC/IS) will be exploited for tumour dose-escalation 715
and/or OAR dose de-escalation (figure 4.1). In tumours with large residual CTVHR volumes at time of brachytherapy, dose-escalation has 716
the potential to improve local control significantly. In limited size CTVHR volumes dose-de-escalation will be performed since dose de-717
escalation has minor impact on local control while it has potential to reduce morbidity. The strategy of EMBRACE II is to aim for an 718
application of the IC/IS technique in at least 20% of the patients in each institution. The threshold of 20% is relevant for a classical stage 719
distribution of ~20% IB, ~50% IIB, ~20% IIIB and ~10% others. If a given patient population includes significantly higher proportions of 720
limited or extensive disease, the threshold of 20% IC/IS applications must be adapted. 721
Figure 4.1 Principles for dose de-escalation and dose escalation in EMBRACE II. The figure shows the current distribution of CTVHR dose 722
and volume in the EMBRACE study (each point represents one patient). A number of 6 dose and volume groups are defined according 723
to cut-points of 85Gy and 95Gy for CTVHR dose and of 30cm3 for CTVHR volume. For each dose-volume group the expected actuarial local 724
control at 3 years is indicated (according to dose effect data from the retroEMBRACE study (Tanderup K. et al. 2014, RetroEMBRACE 725
work in progress). 726
4.1.2 REDUCTION OF VAGINAL SOURCE LOADING 727
A multicenter investigation in 50 EMBRACE patients from 3 institutions (Mohamed SM. et al, in submission 2015) shows that reduced 728
loading in ring/ovoids and increased loading in tandem (and needles when available) can be applied without compromising CTVHR and 729
GTVres dose. Decrease of relative vaginal loading from a mean of 50% to 33% had potential to reduce ICRU recto-vaginal dose by a mean 730
of 4±4Gy, and furthermore, bladder and rectum doses could be reduced by 2-3Gy with the same re-arrangement of loading. Similar 731
evidence is available from a study on simulation of different intracavitary standard loading patterns in EMBRACE patients, where it was 732
shown that limited size tumours could often be covered by tandem loading alone (Nkiwane KS. et al. 2013). 733
4.1.3 SYSTEMATIC UTILISATION OF IMRT 734
Many institutions deliver 3D conformal radiotherapy (3D CRT) based on a four-field box technique although IMRT has been available for 735
a number of years. The practice in EMBRACE has been utilisation of IMRT and 3D CRT in 27% and 73% of the patients, respectively. 736
However, EMBRACE morbidity data as well as data published by Mundt et al (Mundt AJ. et al. 2003) indicate that IMRT significantly 737
reduces the incidence of bowel morbidity, and therefore IMRT is considered as instrumental for reducing the incidence of bowel 738
morbidity and with a potential also to be beneficial for urinary morbidity. 739
740
28
4.1.4 UTILISATION OF DAILY IGRT (SET-UP ACCORDING TO BONY STRUCTURES) 741
PTV margins of 10 mm to the elective lymph node target are currently applied in many institutions. This margin is related to set-up 742
uncertainties with patient positioning performed based on skin marks. However, currently, most institutions have in-room imaging 743
available which makes it possible to perform daily imaging and couch correction according to fusion on bony anatomy. With daily 744
imaging, bony image fusion, and couch correction, a margin reduction from 10mm to 5mm can be performed without compromising 745
target coverage (Laursen LV. et al. 2012). The 5mm margin reduction has potential to decrease the volume irradiated to 43Gy by 746
approximately 500 cm3, which is expected to decrease bowel morbidity by ~50% (Fig. 3.11). 747
4.1.5 EBRT TARGET CONCEPT RELATED TO THE PRIMARY TUMOUR (CTV-T) AND INTERNAL MOTION; 748
CONCEPTS FOR OAR CONTOURING 749
New target concepts are introduced for EBRT related to the primary tumor: initial CTV-T, initial CTV-HR, initial CTV-LR and ITV-LR. The 750
use of this novel contouring approach in conjunction with available MRI will allow to target safely the visible tumor (CTV-T) and the high 751
risk region (CTV-HR intitial) while consenting for dose to a low risk region (CTV-LR initial). Anatomical changes due to bladder and 752
rectal filling variation as well as cervix and uterus position will be considered. An ITV-LR will be outlined using the planning scan and 753
MRI images in patients having a MRI in treating position while a fixed margin will be added to the CTV-LR initial in the patients having 754
only a diagnostic MRI. 755
Some new concepts will be introduced for OAR contouring. Instead of contouring the abdominal cavity, the bowel loops will be 756
outlined in one volume restricted to the outer contour of bowel loops including the mesenterium. This will allow for a better 757
approximation of the bowel loops volume and optimization of the dose constraints. Rectum and sigmoid structures will be contoured as 758
distinct structures. Vaginal lower border will be not more than 2,5cm from the caudal extend of the tumor (2cm in the ITV-LR initial + 759
0,5cm PTV). 760
4.1.6 EBRT DOSE PRESCRIPTION AND REPORTING 761
There is currently a significant variation with regard to EBRT dose and fractionation in the EMBRACE study with doses ranging from 762
45Gy to 50Gy and being delivered in 25-30 fractions. Furthermore, there is a wide variety of lymph node boosting strategies. In 763
EMBRACE II, the EBRT dose and fractionation to the elective lymph node CTV and initial CTV-T is fixed at 45Gy in 25 fractions, and lymph 764
node boosting must be performed as a simultaneous integrated boost. The dose de-escalation from 50Gy to 45Gy has potential to 765
reduce morbidity. A system of reporting dose to targets and OARs is introduced in terms of dose volume parameters and a system of 766
point dose reporting for the vagina. 767
4.1.7 ADAPTATION OF EBRT NODAL ELECTIVE CTV ACCORDING TO RISK OF NODAL AND SYSTEMIC 768
RECURRENCE 769
EMBRACE and RetroEMBRACE data indicate that para-aortic recurrence is the most frequent location of nodal failures (3.2.7, Fig. 3.13). 770
In order to address this pattern of failure, the EMBRACE study will apply a target concept for nodal CTV which includes the para-aortic 771
region in high risk patients. High risk patients are patients with nodal involvement, who have a considerable risk of para-aortic 772
involvement, recurrence and an inferior survival as compared to node negative patients (EMBRACE and RetroEMBRACE work in 773
progress, Schmid MP. et al. 2013). 774
Furthermore, the MD Anderson data have shown that the L5/S1 cranial border of the classical pelvic field for cervix cancer is associated 775
with a high number of failures at this field edge (Beadle BM. et al. 2010), which is in accordance with a recent study from Leuven 776
(personal communication). 777
In addition there is evidence that early disease without risk factors has limited frequency of nodal metastases beyond the iliac 778
bifurcation (1.4% in EMBRACE experience). 779
29
Therefore based on the evidence from EMBRACE, RetroEMBRACE and literature findings, three categories will be defined according to 780
the risk of nodal and systemic recurrence: low risk, intermediate risk and high risk. In the low risk group, the nodal elective CTV will be 781
reduced by exclusion of the common iliac region. In the intermediate risk group the target will include the common iliac nodes with 782
inclusion of the aortic bifurcation, internal iliac, external iliac, obturator, and presacral nodal regions (and groins in case of distal vaginal 783
infiltration). In the high risk group the para-aortic region will be included in the target. 784
The risk groups are defined according to a number of criteria at time of diagnosis which is partly supported by EMBRACE findings and 785
literature support (see chapter 9, table 9.1). 786
4.1.8 SYSTEMATIC APPLICATION OF SIMULTANEOUS CHEMOTHERAPY 787
According to international standard and evidence, simultaneous chemotherapy (min. 5x40 mg/m2 cis Platinum) was prescribed in the 788
EMBRACE protocol for all patients, who qualify for its administration. Certain rules were given for adaption according to international 789
guidelines. Altogether, so far 90-95% of EMBRACE patients received simultaneous chemotherapy, which compares favourably with the 790
78% that received simultaneous radiochemotherapy in RetroEMBRACE, reflecting that the vast majority of EMBRACE patients received 791
chemotherapy according to the EMBRACE protocol. Most of the EMBRACE cohort is consecutive patients representing the cervix cancer 792
patient population in the respective centers. When analysing the number of patients and the number of chemotherapy cycles received, 793
about 70% received ≥ 5 cycles, while 30% received 0-4 cycles. As stated above (3.2.8), administration of chemotherapy has impact on 794
systemic control, which seems to be pronounced in high risk patients (node positive and/or stage III/IV) with a 20% difference in 795
systemic recurrence. Also a center effect has been found in the ability to administer chemotherapy with a variation from 15% and 85% 796
of the patients receiving ≥5 cycles of chemotherapy. In order to reach optimal outcome throughout the cervix cancer population and in 797
particular in the high risk group, the EMBRACE II protocol therefore also focusses on the appropriate administration of chemotherapy 798
according to the EMBRACE II protocol and following international guidelines (chapter 11.1). 799
4.1.9 REDUCTION OF OVERALL TREATMENT TIME 800
Several studies indicate that maintaining an overall treatment time (OTT) of <=50 days is important for local control. RetroEMBRACE 801
data confirms that OTT remains of importance in the realm of IGABT. As there is significant variation of OTT across patients and 802
institutions in retroEMBRACE, the EMBRACE II study aims to reduce the OTT so that the majority of patients (>80%) will adhere to the 803
<=50 day threshold. The measures to reduce OTT in EMBRACE is to systematically apply 25 fractions of EBRT including lymph node 804
boost, and furthermore to carefully plan the BT schedule, so that brachytherapy is delivered towards the end of EBRT and/or directly 805
after EBRT. 806
807
30
4.2 AIMS OF THE EMBRACE II STUDY 808
4.2.1 GENERAL AIMS 809
• To systematically apply IMRT with daily IGRT as well as advanced image guided adaptive BT in a prospective multi-centre setting 810
• To systematically implement a dose prescription protocol for IGABT 811
• To implement systematic contouring, prescription and reporting for EBRT CTV and OARs. 812
• To administer EBRT in different targets which are adapted to the risk of nodal and systemic failure: to improve para-aortic and 813 systemic control in high risk patients and not to decrease lymph node control in low risk and intermediate risk patients 814
• To systematically administer simultaneous chemotherapy to EBRT to reach prescribed dose in as many patients as possible, in 815 particular in high risk patients 816
• To benchmark an outstanding high level of local, nodal and systemic control as well as survival with application of advanced EBRT, 817 BT and chemotherapy within limited overall treatment time 818
• To benchmark a low incidence of intermediate and major morbidity as well as a high level of QoL with application of advanced 819 EBRT, BT and chemotherapy 820
4.2.2 SPECIFIC AIMS 821
• To validate that a dose prescription protocol and increased application of IC/IS will result in: 822
o Dose escalation to the GTV and CTVHR in tumours with large residual volume at time of brachytherapy and increase local 823 control in these tumours without increasing morbidity 824
o Dose de-escalation in vagina, bladder, and rectum with regard to high doses (e.g. >50-60Gy) and improve morbidity 825 without compromising local control 826
• To validate that vaginal source loading and dose to the vagina can be reduced without compromising GTV, CTVHR and CTVIR dose, 827 and that this can reduce vaginal morbidity without compromising local control 828
• To validate dose and volume effect relationships which were demonstrated in the EMBRACE/retroEMBRACE study for 829
GTVres D98, CTVHR D90 and D98, volumes and local control 830 CTVHR D90, CTVHR volume and systemic control 831
• To validate dose effect relationships for morbidity and QoL which were demonstrated in the EMBRACE/RetroEMBRACE study for 832 high doses in small volumes (2 cm3) or points related to brachytherapy administration: bladder, rectum, vagina 833
• To validate that utilisation of IMRT and daily IGRT with reduced margins can reduce the overall body volume irradiated to 45Gy 834 and lead to reduction of GI and urinary morbidity 835
• To validate that reduction of dose from 50Gy to 45Gy to the elective lymph node CTV does not compromise nodal control and 836 leads to reduction of vaginal morbidity 837
• To explore the impact of a systematic application of EBRT CTV-T concepts (with regard to the lower PTV border) on vaginal dose 838 and morbidity 839
• To demonstrate that the application of the initial CTV-T concepts as well as the ITV and PTV margins as prescribed in the protocol 840 does not compromise local control in the primary tumour and uterine body 841
• To explore dose volume effect relationships related to intermediate EBRT dose levels in bladder, rectum, vagina, bowel and 842 overall body volume 843
• To demonstrate that it is feasible to administer simultaneous chemotherapy to EBRT to reach 5 cycles of cis Platinum in the 844 majority of patient (in particular in high risk patients) and that this leads to improvement in systemic control 845
• To evaluate the prognostic significance of SUV in individual lymph nodes for lymph node control 846
• To explore dose and effect relationship of chemotherapy for nodal and systemic control 847
• To identify prognostic parameters and define groups of patients at different risk of local, nodal and systemic failure 848
• To evaluate the impact of continuous web-based and workshop oriented education in contouring and dose planning throughout 849 the study on overall quality and compliance 850
851
31
5 STUDY DESIGN, ENDPOINTS AND HYPOTHESES 852
853
5.1 STUDY DESIGN 854
EMBRACE II is an interventional and prospective multi-centre study which aims at benchmarking an excellent level of local control, 855
nodal control, systemic control and overall survival as well as treatment related morbidity and quality of life in patients with LACC. 856
These aims are targeted through a variety of interventions related to brachytherapy, external beam radiotherapy and chemotherapy. 857
Furthermore, EMBRACE II will prospectively validate the findings on correlations between DVH parameters and outcome as obtained 858
from EMBRACE and RetroEMBRACE for GTV, HR CTV and OARs. The number of patients accrued to the study is determined by the 859
requirement for an appropriate precision (confidence interval) with which disease and morbidity actuarial outcome can be 860
benchmarked at 3 years. 861
The EMBRACE II interventions are expected to improve the clinical outcome of EMBRACE II as compared to the benchmark of the 862
EMBRACE and RetroEMBRACE studies. The EMBRACE II interventions are hypothesized to lead to specific improvements in radio- and 863
chemotherapy dose administration. Based on the clinical outcome benchmarked in EMBRACE and retroEMBRACE as well as the 864
evidence of dose-effect relationships also established in these studies (see background in chapter 3), the treatment related 865
improvements of EMBRACE II are hypothesized to lead to a specific benchmark in terms of actuarial outcomes for disease, morbidity 866
and survival. While disease and patient characteristics of the cohort may change over time, the assumed benefits are expected to be 867
present in comparable groups which are balanced for example according to prognostic and treatment related factors. 868
5.2 ESTIMATE OF PATIENT ACCRUAL AND STUDY PERIOD 869
A number of 16 centers who are currently accruing patients for the EMBRACE study are expected to participate in the EMBRACE II 870
study. According to the accrual rate in 2014, these 16 centers are expected to accrue 200 patients per year for EMBRACE II. 871
Furthermore, new centers have shown interest in EMBRACE II, and it is expected that 10 new centers will be approved for participation 872
and can start accrual in 2016 and 2017, with accrual of 100 additional patients per year. With a study accrual period of 4 years from 873
2016 to 2019, it is expected to reach a total number of patients of 1000 patients: 150 (2016), 250 (2017), 300 (2018), 300 (2019). 874
5.3 HYPOTHESES AND ENDPOINTS 875
Primary endpoints are local control, nodal control, systemic control, overall survival and morbidity and quality of life. Secondary 876
endpoints comprise cancer specific survival, and disease specific survival. 877
In the following the general and specific hypotheses are listed. The specific hypotheses are defined on two different levels. The first 878
level is related to treatment characteristics in terms of technique as well as dose and volume parameters for targets and OARs. These 879
hypotheses are defined based on the expected change of practice in EMBRACE II as compared to the performance in EMBRACE. The 880
second level of specific hypotheses is related to the clinical effects of the change of practice in terms of local, nodal, systemic control 881
and morbidity as well as survival and quality of life. 882
These hypotheses have been designed based on the expected clinical impact of the change of practice in EMBRACE II as compared to 883
EMBRACE I. As starting point for the formulation of the benchmarks the mature data of RetroEMBRACE have been taken for the disease 884
related endpoints. For morbidity the EMBRACE I data have been used. 885
It is well recognized, that the assumed numeric benchmarks may have to be adapted according the observed change of practice in 886
EMBRACE II and the final and mature data of EMBRACE I. 887
888
889
32
5.3.1 GENERAL HYPOTHESIS ON OVERALL SURVIVAL 890
The sum of interventions of EMBRACE II as defined for EBRT, BT and chemotherapy will benchmark a high level of overall survival at 3 891
and at 5 years which is assumed to be 4% superior to RetroEMBRACE. The strongest prognostic predictors for overall survival are at 892
present stage and nodal status, and the hypothesis on overall survival is therefore stated for the overall cohort as well as for two groups 893
according to the risk of disease-related death. The group at lower risk of disease failure is defined as patients with FIGO stage I or II who 894
are also node negative. The group at higher risk is defined as any patients with stage III disease or higher local stage as well as any node 895
positive patients (enlarged nodes, PET positive nodes, nodes proven by histology). In EMBRACE, patients are distributed more or less 896
equally into these two groups: stage III, IV or N+ is 58% and stage I, II and N- is 42%. 897
Hypothesis for Overall Survival (OS): 898
Overall cohort: 81% (3 years) / 71% (5 years) (improvement of 4%) 899
Stage I,II and N-: 88% (3 years) / 83% (5 years) (improvement of 1%) 900
Stage III,IV or N+: 71% (3 years) / 56% (5 years) (improvement of 7%) 901
Limitation: the numbers for EMBRACE represent the status of clinical evidence available in 8/2015. For the final definition of the 902
assumed benchmark (EMBRACE II) the final mature EMBRACE I outcome has to be taken into account when available. 903
5.3.2 SPECIFIC HYPOTHESES ON TECHNIQUE, DOSE AND VOLUMES: 904
Table 5.1 presents the change of practice in EMBRACE II related to the treatment interventions and as categorized into groups related 905
to administration of EBRT, BT and chemotherapy (column 1). The current level of practice in EMBRACE is listed (column 2), and the 906
effect of the change of practice on technique as well as dose and volume parameters has been quantified into a number of hypotheses 907
(column 3). 908
Table 5.1 Specific hypotheses on technique, dose and volume. 909
Change of practice Current practice in EMBRACE EMBRACE II hypotheses: technique, dose, and volume
BT dose escalation / de-escalation in tumours with CTVHR volume ≤30cc
IC/IS in 21% of pts
CTVHR D90 > 85Gy in 80% of pts
CTVHR D90 > 95Gy in 38% of pts
IC/IS in >30% of patients*
CTVHR D90>85Gy in >90% of pts: mean dose escalation of 8Gy in the group previously treated with <85Gy*
Mean dose de-escalation of 5Gy in the group previously treated with >95Gy**
BT dose escalation in tumours with CTVHR volume >30cc
IC/IS in 58% of pts
CTVHR D90 >85Gy: 63% of pts.
IC/IS in >70% of patients*
CTVHR D90>85Gy in >80% of pts: mean dose escalation of 8Gy in the group previously treated with <85Gy*
BT dose de-escalation in bladder, rectum and vagina
Mean vaginal loading: 51%
Bladder D2cm3 <80Gy in 60% of pts
Rectum D2cm3 <65Gy in 62% of pts
Mean vaginal loading <33%**
Mean dose de-escalation**:
Bladder D2cm3: - 4Gy
Rectum D2cm3: - 4Gy
33
ICRU recto-vagina dose <65Gy in 52% of pts
ICRU recto-vagina dose: -8Gy
Bladder D2cm3 < 80Gy in 70% of pts**
Rectum D2cm3 < 65Gy in 70% of pts**
ICRU recto-vagina dose < 65Gy in 70% of pts**
EBRT reduction of OAR irradiation with IMRT and IGRT
PTV margins of 10mm are applied for the elective lymph node target in ~70% of institutions
70% of pts are treated with 45Gy and 30% with >45Gy
Mean volume irradiated to >43Gy:
- IMRT: 2300 cm3
- 3D CRT: 2700 cm3
Margin reduction from 10mm to 5mm will result in reduction of PTV volume of 500cm3**
100% of pts are treated with 45Gy
Mean volume irradiated to >43Gy is:
IMRT/IGRT: <2200cm3**
Adaptation of EBRT nodal elective CTV according to risk of nodal failure
26% (102/395) of N+ pts are treated with para-aortic irradiation****
55% of N+ pts are treated with para-aortic irradiation
20% of N- pts are treated with reduced pelvic fields (low risk)****
Overall treatment time simultaneous integrated lymph node boost
In ~50% of the patients the OTT is <50 days (RetroEMBRACE)
In 80% of the patients the OTT is ≤50 days***
lymph node boost simultaneous, if indicated
Administration of concurrent chemotherapy
≥5 cycles of concomitant cisplatin is administered in 69% of pts
5 cycles of concomitant cisplatin is administered in >80% of pts*
*Based on current performance of advanced EMBRACE I centres 910 **Based on pilot data from the EMBRACE research group 911 ***Based on administration of 25fx (with integrated lymph node boost) as well as increased awareness of the timing of brachytherapy 912 ****Based on disease characteristics in the EMBRACE cohort 913
914
5.3.3 SPECIFIC HYPOTHESES ON CLINICAL ENDPOINTS 915
The specific hypotheses on clinical endpoints are listed in table 5.2. This table shows the current status in RetroEMBRACE and EMBRACE 916
studies (clinical evidence as available in 8/2015) as well as the expected outcome in EMBRACE II (actuarial at 3/5 years). 917
For the definitive numeric benchmarking, the respective final results of EMBRACE I have to be taken into account when available, as 918
well as the observed change in practice in EMBRACE II (5.3.2; table 5.1). 919
Local control: 920
Limited volume (CTVHR≤30cm3): 921
Local control will be maintained in small volume tumours even with dose de-escalation, due to negligible impact of very high 922
doses in small volume tumours and due to reduced overall treatment time (OTT). 923
34
Large volume (CTVHR>30cm3): 924
Local control will be improved by 5% in large volume tumours due to dose escalation and reduction of OTT. The hypothesis is 925
based on evidence that: 926
Improvement of local control is ~0.5% per Gy of dose escalation 927
AND 928
Improvement of local control is ~0.5-1% per day of reduced OTT. 929
Nodal control (incl para-aortic): 930
Stage I, II and N0: 931
In the intermediate risk group, nodal control (incl. para-aortic) will be improved by 1% due to improved identification of 932
pathologic lymph nodes (PET imaging and laparoscopy) and systematic application of large pelvis EBRT reducing nodal 933
recurrence at the cranial target border. 934
In the low risk group (tumour size ≤4cm, stage IA/IB1/IIA1, N0, squamous cell carcinoma, no uterine invasion), the nodal 935
control (98.5%) will not be compromised by reduction of treatment fields. 936
Stage III, IV or N1: 937
In the intermediate risk group, nodal control will be improved by 2% due to improved identification of pathologic lymph nodes 938
(PET imaging and laparoscopy), systematic application of large pelvis EBRT, improved administration of concomitant 939
chemotherapy, and improved hypo-fractioned boosting of pathologic lymph nodes. 940
In the high risk group, nodal control will be improved by 3-4% due to the combined effect of increased administration of para-941
aortic irradiation, improved administration of concomitant chemotherapy, improved identification of pathologic lymph nodes 942
(PET imaging and laparoscopy), as well as improved hypo-fractioned boosting of pathologic lymph nodes. 78% of para-aortic 943
failures in EMBRACE were in patients who did not receive para-aortic irradiation. The administration of para-aortic irradiation 944
will be approximately doubled (from 25% to 50% of N1 patients) in EMBRACE II, and around 25% of the patients with para-945
aortic failure in EMBRACE would have received para-aortic irradiation under the EMBRACE II criteria. Based on this, para-aortic 946
nodal control in N+ patients is assumed to improve by 2-3%, mainly due to increased administration of para-aortic irradiation. 947
Systemic control (excluding para-aortic failures): 948
Stage I, II and N-: 949
Systemic control will be improved by 1% due to improved nodal control. 950
Stage III, IV or N+: 951
Systemic control will be improved by 5% due to improved local and nodal control as well as improved administration of 952
chemotherapy. Chemotherapy administration of ≥5 cycles is related with 25% less systemic recurrences in this patient group, 953
and 10% additional patients will receive ≥5 cycles in EMBRACE II. Also adjuvant chemotherapy will be used in high risk patients 954
according to center decision. 955
Cancer specific survival: 956
Stage I, II and N-: 957
Cancer specific survival will be improved by 1% according to the accumulated effect of 0%, 1%, and 1% improvement in local, 958
nodal, and systemic control, respectively. 959
35
Stage III, IV or N+: 960
Cancer specific survival will be improved by 7% according to the accumulated effect of 3-5%, 4%, and 5% improvement in local, 961
nodal and systemic control, respectively. 962
Overall survival: 963
Stage I, II and N-: 964
Overall survival will be improved by 1% assuming the same improvement as for cancer specific survival 965
Stage III, IV or N+: 966
Overall survival will be improved by 7% assuming the same improvement as for cancer specific survival. 967
Morbidity: 968
Urinary morbidity: 969
G≥2 will be improved by 5% mainly due to BT dose de-escalation which leads to decrease in incidence of G≥2 urinary frequency 970
and incontinence of 1% per Gy of dose de-escalation. Furthermore, the introduction of IMRT is expected to contribute with 971
decreased incidence of G≥2 urinary frequency and incontinence. 972
G≥3 will be improved by 1%. Although there is currently not any dose-effect relationship established for G≥3, it is assumed that 973
bladder dose de-escalation will have a beneficial effect. 974
Rectal morbidity: 975
G≥2 will be improved by 2% mainly due to BT dose de-escalation which leads to decrease in incidence of G≥2 bleeding of 0.5% 976
per Gy of dose de-escalation. 977
G≥3 will be improved by 0.5%. Although there is currently not any dose-effect relationship established for G≥3, it is assumed 978
that rectum dose de-escalation will have a beneficial effect. 979
Bowel morbidity: 980
G≥2 will be improved by 5% mainly due to the introduction of IMRT which has shown a decrease of 5% in patient reported 981
diarrhea (prevalence) as well as tendencies of decreased patient reported problems with bowel control. 982
G≥3 is assumed to be improved by 1%. Although there is currently not any dose-effect relationship established for G≥3, it is 983
assumed that the overall decrease of irradiated volume will decrease also G≥3 morbidity. 984
Vaginal stenosis: 985
G≥2 stenosis will be improved by 7% due to the combined effect of BT dose de-escalation, decreased EBRT dose (prescription 986
of 45Gy pelvic fields to all patients), as well as improved definition of the lower field border. Vaginal stenosis decreases by 0.5-987
1% per Gy of dose de-escalation, and furthermore the incidence of vaginal stenosis is 13% less in patients irradiated to 45Gy as 988
compared to patients irradiated with 50Gy. 989
Overview 990
Table 5.2. Hypotheses of the EMBRACE II study in terms of outcome at 3 years (actuarial). Columns 1 and 2 show the clinical outcome in 991
the retroEMBRACE and EMBRACE studies. The improvement of outcome in EMBRACE II is estimated with retroEMBRACE as baseline 992
(evaluated 9/2014) for disease related outcome and with EMBRACE as baseline for morbidity (2014/2015). Limitation: the numbers for 993
36
EMBRACE represent the status of clinical evidence available in 8/2015. For the final definition of the assumed benchmark (EMBRACE II) 994
the final mature EMBRACE I outcome (when available) has to be taken into account as baseline for both disease related outcome as 995
well as morbidity. 996
retroEMBRACE 3/5y EMBRACE 3y EMBRACE II 3y Confidenc
e interval*
Local control
Overall 91/89% 91% 93% 2%
≤30cm3 HR CTV 96% 96% 96% 2%
>30cm3 HR CTV 87% 88% 91% 3%
Stage IB, IIA 98/98% 95% 98% 2%
Stage IIB 93/91% 90% 94% 2%
Stage III 79/75% 88% 89% 6%
Stage IVA 76/76% 87% 89% 15%
Nodal control (incl para-aortic)
Overall 88% 84% 90% 2%
N- and Stage I+II 93% 91% 94% 2%
N+ and Stage III+IVA 83% 79% 87% 4%
Pelvic nodal control
Overall 94% 89% 95% 1%
Pelvic control (local+nodal)
Overall 87/84% 90% 2%
Systemic control (excluding
para-aortic failures)
Overall 83/79% 83% 86% 3%
N- and Stage I+II 90% 89% 91% 3%
N+ and Stage III+IVA 74% 79% 79% 4%
Cancer specific survival Consecutive ChT
Overall 81/74% - 85/78% 3%
N- and Stage I+II 90/87% - 91/88% 3%
N+ and Stage III+IVA 69/57% - 76/64% 4%
Overall survival Consecutive ChT
Overall 77/67% - 81/71% 3%
N- and Stage I+II 87/82% - 88/83% 3%
N+ and Stage III+IVA 64/49% - 71/56% 5%
Morbidity
Bladder CTCAE ≥ G2 26% 21% 3%
Bladder CTCAE ≥ G3 7% 6% 2%
Rectum CTCAE ≥ G2 11% 9% 2%
Rectum CTCAE ≥ G3 2% 2% 1%
Bowel CTCAE ≥ G2 17% 12% 2%
Bowel CTCAE ≥ G3 5% 4% 1%
Vaginal CTCAE ≥ G2 27% (stenosis)
31% (all)
20% (stenosis)
24% (all)
3%
Vaginal CTCAE ≥ G3 4% (all) 3% (all) 1%
*Based on patient accrual of 1000 patients (95% confidence interval). 997
37
6 EMBRACE OUTLINE 998
999
1000
38
7 STAGING AND PATIENT WORK-UP 1001
All examinations must be completed before treatment and no investigation should be more than 4 weeks old at the time of treatment 1002
initiation. For the purpose of including a patient in the Embrace 2 protocol the following examinations have to be performed: 1003
Patient history and current status including among others information on hormonal status, co-morbidity, previous major 1004 surgery, smoking status (ch. 12, 16, CRF) 1005
General physical examination, including assessment of performance status (WHO) 1006
Blood tests including haemoglobin and lymphocytes 1007
Gynaecological examination (supplemented by cystoscopy and rectoscopy if organ involvement is suspected) with topographic 1008 documentation on a specific cartoon (see appendix) 1009
Biopsy of the primary tumour 1010
Laparoscopic lymphadenectomy is recommended but not required 1011
Pelvic MRI (see in detail Gyn GEC ESTRO Recommendations IV (Dimopoulos JC. et al. 2012) 1012
Preferable whole body (FDG)PET-CT or at least CT scan of thorax, abdomen and pelvis 1013
Assessment of SUVmax in primary tumour and lymph nodes is recommended but not required 1014
Staging according to FIGO and TNM 1015
Baseline Morbidity scoring (ch.12, 16, CRF) 1016
Baseline quality of life questionnaire (ch. 12,16, CRF) 1017
1018
1019
1020
1021
1022
1023
1024
1025
1026
1027
39
8 PATIENT SELECTION 1028
8.1 INCLUSION CRITERIA 1029
Cancer of the uterine cervix considered suitable for curative treatment with definitive radio-(chemo)therapy including MRI 1030 guided BT 1031
Positive biopsy showing squamous-cell carcinoma, adenocarcinoma or adeno-squamous cell carcinoma of the uterine cervix. 1032
Staging according to FIGO and TNM guidelines 1033
MRI of pelvis at diagnosis is performed 1034
MRI, CT or PET-CT of the retroperitoneal space and abdomen at diagnosis is performed 1035
MRI with the applicator in place at the time of (first) BT will be performed 1036
Para-aortic metastatic nodes below L1-L2 are allowed 1037
Patient informed consent 1038
1039
8.2 EXCLUSION CRITERIA 1040
Other primary malignancies except carcinoma in situ of the cervix and basal cell carcinoma of the skin 1041
Small cell neuroendocrine cancer, melanoma and other rare cancers in the cervix 1042
Metastatic disease above and beyond the retroperitoneal para-aortic L1-L2 interspace 1043
Previous pelvic or abdominal radiotherapy 1044
Previous total or partial hysterectomy 1045
Combination of preoperative radiotherapy with surgery 1046
Patients receiving BT only 1047
Patients receiving EBRT only 1048
Patients receiving neo-adjuvant chemotherapy or other forms of antineoplastic treatment apart from weekly concomitant 1049 cisplatin (40 mg/2). However, adjuvant chemotherapy in the form of 4 courses of 3 weekly Carboplatin (AUC 5) and Paclitaxel 1050 (155 mg/m2) is allowed according to departmental policy. 1051
Contra indications to MRI 1052
Contra indications to BT 1053
1054
40
9 EXTERNAL BEAM RADIOTHERAPY 1055
9.1 INTRODUCTION 1056
External beam radiotherapy (EBRT) is an integral part of the overall treatment strategy with the primary aim of obtaining regional and 1057
nodal control. In addition, EBRT provides a basis of homogenous dose on which the steep dose gradient of brachytherapy takes off to 1058
achieve the very high dose needed to obtain local control of the primary tumour. At the same time, the dose outside of the EBRT 1059
target(s) should evidently be as low as possible. Studies comparing IMRT with 3D conformal EBRT, including results from the EMBRACE I 1060
study show that IMRT reduces the incidence of late toxicity (mainly gastro-intestinal). With the growing technical possibilities and 1061
availability of imaging, the field of image guided EBRT (IGRT) is rapidly evolving. A further decrease of treatment related toxicity is 1062
expected from IGRT approaches. For EMBRACE II, pragmatic choices have been made in order to allow safe state of the art treatment 1063
delivery within the current clinical workflows of participating centres. 1064
9.1.1 AIMS OF EXTERNAL BEAM RADIOTHERAPY (COMPARE CH 3-5) 1065
1. To introduce systematically MRI and CT guided IMRT for EBRT in cervix cancer with a tailored target and margin concept and 1066
defined dose prescriptions for tumour and nodal targets 1067
2. To control overall treatment time (90% of all patients <50 days for EBRT and BT) 1068
3. To maintain and improve the excellent pelvic control (local and regional) 1069
4. To improve para-aortic control by elective para-aortic irradiation in high risk patients (HR LN) and by elective common iliac 1070
nodal irradiation (incl. aortic bifurcation) in intermediate risk patients (IR LN) (Table 9.2, Fig. 9.1). 1071
5. To maintain and improve the excellent nodal control through simultaneous hypofractionated integrated boosting (SIB) and 1072
coverage probability (CoP) dose planning for treatment of pathological lymph nodes 1073
6. To reduce EBRT related morbidity through reduction of target volume as well as the treated and irradiated volumes: 1074
Excluding the common iliac region from the elective target volume in low risk patients (LR LN) (Table 9.2) 1075
Reducing set-up error and allowing for PTV margin reduction for the nodal CTV-E (5 mm) and the ITV-T LR through 1076
performing daily 3D IGRT with daily online couch correction based on bony anatomy (Fig. 9.9) 1077
Introducing an initial CTV-THR and an initial CTV-TLR based on the primary tumor extent (initial GTV-T) (Fig. 9.2-9.8) 1078
Recommending an internal target volume (ITV-T LR) approach for the primary tumour (CTV-T LR) (Fig. 9.9) 1079
Using inverse treatment planning techniques (IMRT, VMAT or Tomotherapy) applying systematically dose volume 1080
constraints for EBRT 1081
9.1.2 NODAL TARGETS BASED ON RISK GROUP ALLOCATION FOR NODAL SPREAD 1082
The risk of lymph node spread is dependent on various factors. Among the most important are the local spread (FIGO stage), histology 1083
and lymph node spread. The pattern of lymph node recurrence has two predominant areas: within the radiation field in the obturator 1084
region (in-field), at the cranial field border (marginal) and in the para-aortic region (outside radiation field) (Verma J. et al. 2014 and 1085
EMBRACE/RetroEMBRACE work in progress). 1086
In order to tailor the nodal target according to the assumed risk of microscopic nodal involvement three risk groups are introduced with 1087
three different elective nodal target volumes. The aim is to reduce morbidity in the low risk group and to improve nodal and systemic 1088
control in the intermediate and high risk group. 1089
To summarize the indications for nodal targets based on risk group allocation for lymphatic spread (table 9.1): 1090
Small pelvis EBRT in low risk patients (LR LN) 1091
Large pelvis EBRT in intermediate risk patients (IR LN) 1092
Large pelvis + para-aortic EBRT in high risk patients (HR LN) 1093
41
Risk allocation is based on primary tumour characteristics and nodal pathology at time of diagnosis and takes into account the 1094
probability of developing lymph node metastases in pelvic and para-aortic areas. Risk groups are defined in table 9.1, and criteria for 1095
categorising a lymph node as pathologic are defined in table 9.2. This is a general outline, giving the major pathways for tailoring nodal 1096
targets based on risk group allocation. Such general outline leaves some space for specific clinical situations where some outstanding 1097
clinical features (not listed in detail here) may be taken into account, such as large lymph node size, for defining e.g. a high risk group. 1098
1099
Table 9.1: Risk groups for defining the elective clinical target volumes for lymph nodes and corresponding nodal targets defining the 1100
radiation field extensions. 1101
Risk Group LN Definition EBRT lymph node regions
Low Risk (LR LN)
Tumour size ≤4cm AND stage IA/IB1/IIA1 AND N0 AND squamous cell carcinoma AND no uterine invasion
“Small Pelvis”
internal iliac external iliac obturator presacral
Intermediate Risk (IR LN)
Not low risk
No high risk features
“Large Pelvis”
Nodes included in “Small Pelvis” and common iliac region (including the aortic bifurcation). In addition:
inguinal in case of distal vaginal involvement.
Mesorectal space in case of mesorectal nodes and advanced local disease
High Risk (HR LN)
Based on nodal pathology
≥ 1 pathologic node at common iliac or above
OR ≥ 3 pathologic nodes
“Large Pelvis + Para-aortic”
Nodes included in “Large Pelvis” and para-aortic region with the upper border of CTV minimum at the level of renal veins (usually incl. L2), and at least 3 cm cranial of the highest pathological node in case of para-aortic nodes].
1102
Table 9.2: Definition of pathologic lymph nodes based on volumetric imaging 1103
Pathologic lymph node FDG PET positive
And/OR: short axis ≥ 1 cm on CT or MRI
And/OR: short axis between 0.5-1.0 cm on MRI with pathological morphology: irregular border, high signal intensity and/or round shape
1104
1105
42
1106
Fig 9.1 Schematic Diagram for lymph node elective CTVs based on risk of lymphatic spread, “Small Pelvis”, “Large Pelvis”, “Large Pelvis + 1107
para-aortic” (compare table 9.1) 1108
1109
9.2 PREPARATIONS FOR TREATMENT PLANNING 1110
Gynaecological examination with appropriate documentation on cartoons (see chapter 10), diagnostic T2 weighted MRI and a 1111
treatment planning CT in supine position are minimal requirements for target delineation and treatment planning. PET-CT is strongly 1112
recommended, but optional. Slice thickness of the treatment planning CT scan should be ≤ 3 mm. The use of intravenous contrast 1113
media for the treatment planning CT is optional but use is recommended to ease identification of structures of interest. The choice for 1114
immobilization devices is according to the clinical routine of the individual institutes. 1115
It is recommended, but not mandatory, to perform an empty bladder scan on top of the comfortably filled bladder scan. Full and empty 1116
bladder scans give information about the range of internal motion of the target volumes, and this can be exploited when defining an 1117
individualized ITV as discussed in section 9.3.3. Having multiple (diagnostic and treatment planning) imaging series available with 1118
different combinations of bladder and bowel filling, usually from different days contributes further to defining the individualized ITV. 1119
high risk
intermediate risk
low risk
L2
L3
L4
L5
S2
43
Ideally both the FDG PET-CT and MRI should be performed in treatment position, in order to enable optimal image fusion based on 1120
bony anatomy, but this is not mandatory. Thus, pertinent diagnostic-imaging sequences may be used. Further recommendations are to 1121
obtain the MRI in three orthogonal planes; to include the aortic bifurcation (cranial) and the inferior border of the symphysis (caudal) as 1122
scan borders and to limit the slice thickness to ≤ 5 mm. 1123
Minimization of internal motion at the time of dose planning scans and during treatment is difficult to achieve. The following measures 1124
have the goal to prevent taking outlier situations into account when deciding on internal organ motion and to attempt to be as 1125
reproducible as possible throughout the period of treatment. 1126
Bladder is intended to be comfortably filled on the treatment planning CT scan and throughout the treatment. Therefore a drinking 1127
protocol is mandatory with specifications on 1) timing of voiding and 2) timing and volume of fluid intake. An acceptable drinking 1128
protocol would be that the patients are asked to void 1 hour before imaging and each EBRT fraction, then drink 300-500 ml of 1129
water/clear fluid and try not to void before treatment delivery. 1130
The rectum and sigmoid should be as empty as possible. The patient is asked to empty the stools before scanning and treatment. If 1131
significant gas or filling is discovered while scanning for treatment planning (diameter of gas or filling in rectum > 4 cm maximum 1132
extension in any direction), the patient should be asked to empty the rectum or deflation with a catheter or postponing the treatment 1133
planning CT to another day could be considered. Special diets with the purpose of reducing internal motion of the gastro-intestinal 1134
system are so far ineffective and therefore currently not recommended. The same applies to the use of enemas since there is concern 1135
about related gas production. 1136
1137
1138
44
9.3 TUMOR AND TARGET DEFINITION AND CONTOURING: INITIAL GTV, INITIAL HR CTV-T, INITIAL LR 1139
CTV-T, ITV-T; GTV-N, CTV-N, CTV-E; PTV 1140
9.3.1 GENERAL OVERVIEW 1141
The volumes of interest are in principle defined according to ICRU 50/62/83: 1142
1143
1144
1145
1146
1147
1148
Tumour and target contouring for EBRT requires an integration of the spatial information obtained at diagnosis by fused MRI, treatment 1149
planning CT, FDG PET-CT if available, and by gynaecological examination. 1150
GTV-T (GTV-N) is defined and contoured based on imaging (MRI (PET-CT)) and clinical characteristics. 1151
CTV is defined and contoured based on the extension of the GTV and the assumed microscopic spread for each specific tumour 1152
extension and its biological characteristics taking into account anatomical regions (e.g. vagina), compartments (e.g. parametrium) and 1153
borders (e.g. outer rectal wall). 1154
ITV is based on a standard or individualized margin. 1155
PTV is derived from the ITV or the CTV using an isotropic margin. 1156
1157
With regard to the primary tumour target (CTV-T) - when using MRI - the GTV-T, and an initial high and low risk CTV-T can be identified. 1158
These definitions correspond to those introduced for the adaptive HR CTV-T for brachytherapy (GEC ESTRO Recommendations, ICRU 1159
Report 88): 1160
The initial HR CTV contains the initial GTV inside and outside the cervix and as a minimum the whole cervix as it presents at 1161
diagnosis. 1162
The initial LR CTV includes the initial HR CTV as starting point. A margin of 20 mm is defined towards the vagina. The whole 1163
uterine corpus is included. The anterior border is defined at about 5 mm anterior towards bladder and about 5 mm posterior 1164
towards rectum at the level of the cervix (Further details are given in 9.3.1 and in the appendix on EBRT Treatment Planning.) 1165
Identification of such sub-volumes for the CTV-T is important as they allow for tailored treatment with different dose prescription (HR 1166
CTV-T, (IR CTV-T), LR CTV-T (see chapter 10), and as they change during treatment. 1167
The initial HR CTV-T and LR CTV-T require different ITV margins according to the location of its borders and their specific motion 1168
uncertainties (e.g. laterally fixed parametrial borders, posterior-anterior mobile borders towards rectum and bladder, overall mobile 1169
borders uterine corpus). The detailed contouring of the initial HR CTV-T and LR CTV-T in 3D can therefore play an important role in the 1170
(individualized) ITV-T concepts. Such contouring enables to reflect the uncertainties due to different motion types at the various CTV 1171
borders when defining the ITV-T (see Appendix on EBRT Treatment Planning). 1172
GTV: Gross Tumor Volume (at diagnosis).
CTV: Clinical Target Volume = GTV + suspected microscopic tumor extension.
ITV: Internal Target Volume = CTV + internal margins to compensate for internal motions.
PTV: Planning Target Volume = CTV (or ITV) + set-up margin.
45
The CTV-T to ITV-T margin for the primary tumour target accounts for uncertainties in size, shape and position of the CTV-T within the 1173
patient, which include both inter- and intra-fraction motion. 1174
The total CTV-T to PTV-T margin needs to accommodate random and systematic geometrical errors that are among others caused by: 1175
internal organ motion (ITV-T) (e.g. uterine cervix, uterine corpus; rectum, bladder filling status) and geometrical errors in positioning 1176
during the course of EBRT for the tumor and lymph node related CTVs (set-up errors). An ITV is most helpful in situations where 1177
uncertainties concerning the geometrical CTV location are greater than setup uncertainties, such as may be the case for a primary 1178
cervical tumour in a mobile uterus (ITV-T). 1179
The elective nodal CTV of the combined draining nodal regions (CTV-E) is selected according to risk of nodal spread. These nodal regions 1180
may be the “Small Pelvis”, “Large Pelvis”, or “Large Pelvis + Para-aortic” (table 9.1). No ITV is defined for the elective nodal target (CTV-1181
E) as internal organ motion seems to play no important role for the CTV-E. 1182
GTVs of pathologic lymph nodes (GTV-N) and their CTVs (CTV-N) are drawn individually. They are included in the CTV-E. 1183
The initial LR ITV-T and the CTV-E form together the ITV 45. The ITV 45 is the basis for the overall PTV which includes the CTV-T and the 1184
CTV-E and, if present, also the CTV-N. 1185
1186
As noted above the nomenclature for many volumes of interest follows the ICRU tradition. 1187
In addition some protocol specific nomenclature is used: 1188
For the subdivision of the primary CTV-T as initial HR CTV-T and initial LR CTV (following in principle the ICRU/GEC 1189
ESTRO definitions for the adaptive CTV for brachytherapy (ICRU 88) (for clarification the suffix “initial” has to be used) 1190
and 1191
For the elective nodal target, which is called “CTV-E” along the tradition of EMBRACE I (instead of CTV-N). 1192
The general definition of the different volumes is given in Table 3. The purpose is to facilitate consistent reporting between 1193
investigators and the Embrace Study Office along the lines of EMBRACE I. Target definition and contouring are described in more detail 1194
in section 9.3. 1195
1196
46
Table 9.3. Protocol specific nomenclature of volumes of interest. 1197
GTV-Tinit Initial Gross Tumour Volume of the primary Tumour
CTV-T HRinit Initial High Risk Clinical Target Volume of the primary Tumour
CTV-T LRinit Initial Low Risk Clinical Target Volume of the primary Tumour
ITV-T LRinit Initial Internal Target Volume of the primary Tumour
GTV-N (#) Gross Tumour Volume of individual pathologic lymph Nodes; these are numbered as GTV-N1....GTV-N2....GTV-N3...., etc.)
CTV-N (#) Clinical Target Volume of individual pathologic lymph Nodes; these are numbered according to the corresponding GTV-N
PTV-N (#) Planning Target Volume of individual pathologic lymph Nodes; these are numbered according to the corresponding GTV-N
CTV-E Clinical Target Volume of the elective nodal region, including pathological lymph nodes if present
ITV45 ITV-T LR + CTV-E for 45 Gy
PTV45 Planning Target Volume for 45 Gy
To maintain consistent reporting and communication between investigators and the Embrace Study Office the protocol for contouring 1198
AND naming of the targets (Table 9.3.) must be followed strictly. 1199
The tumour and target volumes of interest for EBRT are defined in detail in the following paragraphs. 1200
1201
9.3.2 INITIAL GTV AND CTV RELATED TO PRIMARY TUMOUR (GTV-T INIT, CTV-T IN IT (HR, LR)) 1202
1. GTV-T: 1203
Extension of the primary cervix tumour (inside and outside the cervix) 1204
(defined by T2 weighted MRI, supported by clinical investigation, FDG PET-CT information). 1205
2. CTV-T HR: 1206
GTV-T and any remaining cervix not infiltrated by tumour. 1207
3. CTV-T LR: 1208
a. Initial CTV-T HR 1209
b. The complete parametria bilaterally 1210
c. The entire uterus 1211
d. Uninvolved vagina with a 20 mm margin measured from the most inferior position of the initial HR CTV-T, along the 1212 vaginal axis (not starting in the fornix) 1213
e. CTV-T HR plus a margin of about 5 mm anterior and posterior towards bladder and rectum (excluding the non-1214 involved walls) 1215
47
f. In case of involvement of the pelvic wall, sacro-uterine ligaments, meso-rectum or other involved structures a 20 mm 1216 margin around the initial HR CTV-T will be extended into these structures. 1217
g. Any pathological lymph nodes in the parametrium may be included 1218
1219
1220
Figure 9.2 MRI at diagnosis (T2 weighted) of stage IIB cervical cancer with the tumour throughout the whole cervix and infiltrating both 1221
parametria. The initial GTV-T is indicated, which is in this case identical to the initial HR CTV-T, and the initial LR CTV-T including both 1222
parametria, upper vagina and the uterine corpus (from ICRU 88, 2015 in press).. 1223
1224
Figure 9.3. Schematic diagram for cervical cancer, stage IIB, invading most of the cervix with unilateral parametrial extension (at 1225
diagnosis). The initial GTV-T (blue), the HR CTV-T (red line) and the LR CTV-T are indicated. 1226
In the following, typical examples for initial GTV-T, initial CTV-T HR and initial CTV-T LR for EBRT are shown for various tumor extensions 1227
and clinical stages. These figures have been elaborated based on the initial GTV-T demonstration as shown in the figures 10.1-10.5. 1228
They are therefore complementary to those figures taken from ICRU report 88 with typical examples for residual GTV-T, adaptive CTV-T 1229
HR, CTV-T IR and adaptive CTV-T LR for the brachytherapy boost (chapter 10). See also Figures 2-5 in Appendix on EBRT Treatment 1230
Planning (App Fig. 2-5) 1231
48
1232
1233
Figure 9.4 (compare figure 3.1 for brachytherapy): Schematic diagram for cervical cancer, limited disease, stage IB1, with initial GTV-T, 1234
initial CTV-T HR (cervix) and initial CTV-T LR (margins for whole parametria, whole uterine corpus, upper third of vagina, utero-bladder 1235
and cervix-rectum space) for EBRT: coronal, transversal and sagittal view. (modified from Fig. 5.8 from ICRU report 88). 1236
1237
Figure 9.5: (compare figure 3.2 for brachytherapy). Schematic diagram for cervical cancer, stage IB2 (bulky disease) with GTV-Tinit, CTV-T 1238
H Rinit and CTV-T LRinit for EBRT: coronal, transversal and sagittal view. (modified from figure 5.9 from ICRU report 88 1239
49
1240
Figure 9.6 (Compare figure 3.3 for brachytherapy) Schematic diagram for cervical cancer, stage IIB bulky disease, large GTV-Tinit,, initial 1241
CTV-T HR, and initial CTV-T LR: coronal, transversal and sagittal view. (modified from figure 5.10 from ICRU report 88). 1242
1243
Figure 9.7 (compare figure 3.4 for brachytherapy). Schematic diagram for cervical cancer, IIIB, extensive disease, large initial GTV-T 1244
(GTV-Tinit), initial CTV-T HR, and initial CTV-T LR for definitive treatment: coronal and transversal view. (modified from figure 5.11 from 1245
ICRU report 88). 1246
50
1247
Figure 9.8 (compare figure 3.5 for brachytherapy). Schematic diagram for cervical cancer, with bladder infiltration, stage IVA, large 1248
initial GTV-T (GTV-Tinit) and CTV-T HR, initial CTV-T LR: coronal, transversal and sagittal view. (modified from figure 5.12 from ICRU 1249
report 88). 1250
9.3.3 GTV AND CTV FOR PATHOLOGIC LYMPH NODES (GTV-N, CTV-N) 1251
1. GTV-N: Individual GTV-N for each pathological lymph node (defined in Table 1) is contoured (for dose reporting purposes), also 1252
if nodal booing is not considered. The outer-contour of the pathological node and visible (macroscopic) extra capsular 1253
extension on MRI or CT is included in the GTV-N. GTV-N is contoured on MRI within the field of view. PET-CT should primarily 1254
be used for overall guidance and not for precise delineation of the pathological nodes. In case of nodes beyond the field of 1255
view of the pelvic MRI, individual contours should be based on PET-CT and planning CT appearance. Each GTV-N should be 1256
numbered individually using the exact protocol nomenclature. (App Fig. 9) 1257
2. CTV-N: In principle CTV-N is equal to GTV-N. However, an individualized margin may be considered for each pathologic lymph 1258
node around each GTV-N taking into account extra-capsular extension and possible progression during treatment planning 1259
interval, avoiding bones and muscles. Furthermore, partial volume effect may lead to different appearance of the upper and 1260
lower boundary on CT and MRI. The total CTV-N should encompass the maximum extension as visualized on both CT and MRI. 1261
Typically the GTV-N to CTV-N margin amounts to 0-3 mm. The numbering of individual CTV-N should be consistent with GTV-N. 1262
(App Fig. 9). 1263
1264
9.3.4 CTV FOR NODAL REGIONS WITH ASSUMED MICROSCOPIC DISEASE (CTV-E) 1265
CTV-E: nodal regions to be included in CTV-E depend on the risk of spread and are specified according to the different risk groups 1266
(low, intermediate, high): “Small Pelvis”, “Large Pelvis”, “Large Pelvis + Para-aortic” (Table 9.1, Figure 9.1 and Appendix Fig. 10-15). 1267
a. Nodal regions include the relevant vessels with at least 7 mm perivascular tissue including pertinent clips or lymphocysts (in 1268
case of prior nodal resection or lymphadenectomy). For details concerning anatomical boundaries and margins see appendix 1269
EBRT treatment planning. 1270
b. Any pathological node within the nodal regions must be fully encompassed. 1271
c. In case lymphocysts shrink extensively during ERBT, re-contouring and re-planning should be considered. 1272
d. In case of excessive uterine/ligamentum latum infiltration, consider to include ovaries into CTV-E. 1273
51
9.3.5 ITV (ITV-T) 1274
The ITV - required for optimal target coverage - depends on internal target motion and on the level of image guidance during the course 1275
of fractionated radiotherapy (IGRT). Major shifts may be expected for CTV-T LR especially in the anterior-posterior direction and have to 1276
be accounted for in ITV-T LR with appropriate margins. 1277
No ITV is defined for the elective nodal target (CTV-E). 1278
Different levels of IGRT can be recognized for image guidance and IMRT for cervix cancer EBRT: 1279
1) Basic IGRT: standard margins from CTV-T to ITV-T are applied to compensate for internal target motion. Daily online position 1280
verification and couch correction based on bony landmarks is required using CBCT, kV or EPID imaging to achieve the aimed decrease in 1281
set up errors and corresponding reduction of the PTV margin. CBCT may be used for daily monitoring of uterus movement to decide if 1282
re-planning would be an advantage according to the motion patterns observed. 1283
2) Intermediate IGRT: the CTV-T to ITV-T margin is individualized based on multiple pre-treatment imaging series that allow the 1284
assessment of the individual range of internal target motion. The different images should include different fillings of bladder, which can 1285
be achieved by acquiring full and empty bladder scans or by using images obtained on different days. By doing so, the ITV-T can become 1286
more representative for the expected range of motion in the individual case. CBCT imaging is used for daily online position verification 1287
and couch correction based on bony registration. CBCT may be used for daily monitoring of uterus movement to decide if re-planning 1288
would be an advantage according to the motion patterns observed. 1289
3) Advanced IGRT: is based on individual library plans in which different plan specific ITV-T margins are applied. At this point in time the 1290
library plan approach has been integrated into clinical workflow in some institutions. In this situation daily CBCT is required to select the 1291
ITV-T and treatment plan that best covers the CTV-T on that day. 1292
In EMBRACE II, basic IGRT is minimally required and intermediate IGRT is recommended. Intermediate IGRT is recommended since it is 1293
expected to result in an ITV-T LR that is better representing the motion in the individual case. Advanced adaptive IGRT is allowed 1294
whenever an institution has this advanced approach clinically implemented. Furthermore, an optional sub-protocol for application of 1295
daily library plans (adaptive EBRT) will become available in EMBRACE II as an amendment to the protocol. 1296
1297
9.3.6 STRATEGIES TO DERIVE THE ITV-T LR 1298
a) Basic IGRT, standard margin approach (Fig. 9.9.A) 1299
The ITV-T LR includes (see also App. EBRT for Treatment Planning Figure 7): 1300
CTV-T LR with the following margins: 1301
o 10 mm anterior-posterior 1302
o 10 mm superior-inferior 1303
o 5 mm lateral 1304
At the distal vagina no additional margin along the vaginal axis in the inferior direction is applied 1305
The ITV-T LR should not go into the muscle and bony boundaries of the pelvis (in particular, manual adaptation is needed in the 1306
lateral parametria) 1307
In case of tumour involvement of the upper and most mobile uterus an extra 5 mm margin should be applied in all directions 1308
from the uterus body 1309
Importantly, a clinical judgment has to be made if the CTV structures as presented on the MRI and treatment planning CT are more or 1310
less in the expected average position, based on the rectal and bladder filling state. Having multiple diagnostic image sets fused with the 1311
treatment planning CT, facilitates this judgement. If the target volume is not in the average situation, this should be taken into account 1312
52
in the margins applied in a given patient. For example if the rectum is completely empty it is unlikely that the target volume will be able 1313
to move the full 10-15 mm in the posterior-inferior direction. If the bladder is empty (which is, however, unlikely since the aim for the 1314
treatment planning CT is a comfortably filled bladder) it is unlikely that the target volume will move the full 10-15 mm in the anterior-1315
inferior direction. It should be kept in mind that several studies found that the average bladder volume decreases during the course of 1316
treatment. It is expected that the ITV-T LR contours are modified based on clinical judgement. Reducing the margin in one direction 1317
implies normally that the margin is increased to the same degree in the contralateral direction. The minimal required margin in 1318
anterior-posterior and superior-inferior directions is 5 mm. 1319
b) Intermediate IGRT, individualized ITV-T approach (Figure 9.9.B): 1320
The key difference for an individualized ITV-T compared to the standard margin approach is that pre-treatment imaging, both 1321
diagnostic and for treatment planning, is used to assess the range of motion in an individual patient. A pre-requisite is that these 1322
imaging series have different filling status of bladder and rectum. For this purpose a full and empty bladder treatment planning CT can 1323
be useful. For patients with a smaller range of motion, a smaller ITV margin can be applied, whereas, in patients with a large range of 1324
motion, a margin comparable or larger than that derived from standard motion range may be required. 1325
To generate the ITV-T LR, the different diagnostic and treatment planning image series should be fused to the treatment planning CT 1326
with comfortably filled bladder. The ITV-T LR margin is adapted based on the assessed range of motion within the individual patients, 1327
keeping in mind the proposed standard motion ranges (figure 9.9). 1328
The margins used under “standard margin approach” should be the starting point and individualisation can be adapted from there. ITV-1329
T LR should not go into the muscle and bony boundaries of the pelvis. Importantly, the ITV-T does not need to include the whole uterus 1330
as seen on an image series with an empty bladder, since with the drinking protocol this situation is not expected during the course of 1331
fractionated EBRT. It should be kept in mind though that some studies indicate that the average bladder volume decreases during the 1332
course of treatment. If daily soft tissue verification (CBCT) is used to monitor the daily uterus position, it is possible to shrink the 1333
individualised margins further according to the thresholds defined for re-planning. 1334
9.3.7 GENERATING THE ITV45 1335
The combined ITV-T LR and CTV-E is the target volume which has to be treated with the prescribed dose of 45 Gy by EBRT (see 9.5). It 1336
also contains any CTV-N. This combined tumour and lymph node related target volume is named ITV45. This final ITV45 is required for 1337
dose reporting. 1338
9.3.8 PTV 1339
A PTV margin of 5 mm is applied for the whole ITV 45 which includes the CTV-E and the ITV-T LR (Fig. 9X and 9Y). This margin is 1340
considered appropriate when using daily image guidance and daily couch correction according to bony fusion (see section 9.6). 1341
The PTV45 is consequently the ITV45 with an isotropic margin of 5 mm 1342
For the involved nodes, PTV-N (#) is CTV-N (#) with an isotropic margin of 5 mm. Each individual pathologic node (#) will have an 1343
individual PTV-N (#). PTV-Ns are usually encompassed by PTV45. If they are not encompassed, a larger margin of e.g. 10 mm from the 1344
CTV may be considered in the specific region. 1345
1346
1347
1348
1349
53
A
B
C
Figure 9.9. Panel A shows the application of the “Standard margin” approach where the ITV is defined according to the anatomy in the 1350
CT treatment planning scan. Panel B and C show examples of a “small mover” and “large mover”, respectively, and application of the 1351
“Individualised ITV approach”. Further examples of “Standard margin” and “Individualised ITV approach” can be found the appendix 5 1352
“Contouring Atlas for EBRT”. 1353
1354
1355
54
9.4 CONTOURING OF ORGANS AT RISK, REFERENCE POINTS 1356
The outer contour of the following organs should be delineated separately: 1357
Bladder Whole organ including the bladder neck
Rectum From the ano-rectal sphincter to the recto-sigmoid junction
Sigmoid From the recto-sigmoid junction to the left iliac fossa
Bowel Outer contour of bowel loops including the mesenterium
Femoral heads Both femoral head and neck to the level of the trochanter minor
Reference points:
Vagina Lower and mid-vagina doses (PIBS, PIBS ± 2 cm)
For para-aortic irradiation in addition:
Kidneys Outer contour excluding renal pelvis
Spinal cord Outer contour
Optional (if para-aortic RT above L1 is applied):
Duodenum Whole organ
In case of ovarian transposition
Ovary Outer contour
9.5 CONTOURING OF TUMOUR, TARGETS AND OARS BASED ON MRI AND CT 1358
Treatment planning is performed on the treatment planning CT with a comfortably filled bladder. The T2 weighted transversal plane 1359
MRI is fused to the CT, based on anatomy of the pelvic bones. If MRI is made in the treatment position (flat couch and with bladder 1360
filling protocol) the fusion is usually excellent and MRI can be used for contouring all targets and OAR in the whole cranio-caudal length. 1361
In these cases additional contouring on planning CT might only be needed for the para-aortic part in case of high risk disease. 1362
If diagnostic MRI scans are used, fusion may be more challenging. Priority should be set at achieving an acceptable match within the 1363
pelvis. In these cases it is preferable to use the anatomy as seen on the treatment planning CT for contouring when moving outside the 1364
area of acceptable match. It is recommended to start contouring on MRI, exploiting the superior soft tissue resolution when delineating 1365
GTV-T and CTV-T HR. As there is usually no bladder filling protocol in diagnostic MRI, the location of OARs and uterus is often not 1366
representative, and the next step of contouring normally proceeds on the treatment planning CT to delineate CTV-T LR, ITV-T LR, nodal 1367
targets (GTV-N’s and CTV-E) and OARs (see figure 9.10). However, if there is an excellent fusion between diagnostic MRI and treatment 1368
planning CT, it may be possible to perform GTV-N, CTV-E and OARs on the diagnostic MRI. 1369
55
1370
Figure 9.10 Schematic workflow for contouring primary target and nodal target and OARs on diagnostic MRI, MRI in treatment position 1371
and CT (see also ch. 26 on EBRT treatment planning, Appendix). 1372
9.6 DOSE AND FRACTIONATION FOR PTV45 1373
The planning aim dose and fractionation schedule for PTV45 is 45 Gy delivered in 25 fractions, 1 fraction per day and 5 fractions per 1374
week. All beams and segments involved in a given part of the treatment must be treated at each fraction. Unplanned treatment breaks 1375
(>2 consecutive treatment days) should be compensated by two daily EBRT fractions spaced by at least 6 hours. This compensation 1376
should only be performed once per week, i.e. the dose accumulation of EBRT in the PTV45 should not exceed 10.8 Gy per week. 1377
Maximal overall treatment time including external beam radiotherapy, brachytherapy and concomitant chemotherapy is 50 days. 1378
The dose to the PTV45 should be homogenous, with at least 95% of the PTV covered by the 95% prescription isodose, and dose 1379
maximum less than 107% of the prescribed dose. 1380
Special attention is needed for the OAR irradiation in close proximity to the CTV-T HR (bladder, rectum, sigmoid and bowel) where the 1381
high BT dose will be delivered. To ensure even less dose variation in this region, where summation of EBRT and BT dose is critical, a 1382
helper contour with a margin of 10 mm might be generated around the CTV-T HR (CTV-T HR +10mm). The dose within this helper 1383
contour should be less than 103% of 45Gy to avoid hotspots in OAR walls which are likely to also receive considerable BT dose. 1384
9.7 DOSE AND FRACTIONATION FOR PTV-N (NODAL BOOSTING) 1385
The decision for nodal boosting is left to the individual centre. However, all pathological nodes (with the features described in section 1386
9.3.3.) should be contoured and numbered individually. 1387
Nodal boosting should be performed by use of a simultaneous integrated boost (SIB), with a total number of fractions of 25. Dose 1388
prescription to the individual PTV-Ns (PTV-N1, PTV-N2, PTV-N3, etc.) is left to the treating centre. In every case, EBRT dose have to be 1389
specified for dose reporting, and, if possible, (expected) contribution from BT to the total EQD2 of the specific node. Biological 1390
equivalence calculations are performed by use of the linear-quadratic formulation assuming that the alpha/beta value is 10 Gy for 1391
tumour effects. 1392
Dose from BT to each individual node can be calculated based on BT MRI information. However, the expected PTV-N dose contribution 1393
from brachytherapy can also be accounted for (Mohamed SM. et al. 2015): 1394
56
3-4 Gy EQD2: Inside true pelvis (external/internal iliac, obturator) 1395
Negligible: Outside true pelvis (common iliac, para-aortic, inguinal) 1396
Although institutional practise for nodal boosting and dose levels can be followed, the recommendation given within this protocol for 1397
the nodal boost is that total EBRT + BT dose should preferably be in the range 55-65 Gy EQD2. 1398
Total dose to PTV-Ns of about 60 Gy EQD2 can be achieved with the following fractionation schedules: 1399
Inside true pelvis: EBRT with SIB 25x2.2Gy= 55Gy physical dose. This schedule is equivalent to 56 Gy EQD2 EBRT + 3-4 Gy EQD2 1400 from BT which results in a total dose of ~60 Gy EQD2. 1401
Outside true pelvis: EBRT with SIB 25x2.3Gy =57.5 Gy physical dose. This schedule is equivalent to ~59 Gy EQD2 and BT dose 1402 contribution is negligible. 1403
1404
9.8 TECHNIQUE AND PROCEDURES FOR EBRT INCLUDING DAILY IMAGE GUIDANCE 1405
A major aim of the Embrace II study is to optimize EBRT dose distributions in order to minimize the dose to OAR delivered with EBRT. 1406
This goal implies the mandatory use of IMRT, VMAT or tomotherapy based on inverse treatment plan optimisation. Photon energy of 18 1407
MV is related with increased neutron dose, and therefore lower energies (e.g. 6 MV or 10 MV) are advantageous in this respect for 1408
IMRT/VMAT. However, for higher energies the treatment plan quality is advantagous in terms of decreased low dose volumes for 1409
IMRT/VMAT. These two aspects need to be considered when deciding on photon energy. 1410
It is recommended to use coverage probability (CoP) dose planning principles for lymph node boosting. With CoP planning principles it 1411
is assumed that the CTV-N is more often occupying the central region of the PTV-N than the edge region. According to this, it is aimed 1412
to generate a heterogeneous dose across the PTV-N in such a way that the central dose >100% and the edge dose is cooled down to 1413
90%. In case of large lymph nodes it is possible to escalate the central part of the GTV-N to e.g. D50>102%, while respecting an upper 1414
limit of 107%. 1415
Daily 2D (MV or kV) or 3D (CBCT or MVCT) IGRT is mandatory. The daily imaging is used for fusion and position verification on bony 1416
anatomy. Couch correction must be performed daily before treatment delivery according to the bony fusion between the on-board 1417
imaging and the treatment planning CT. Couch alignment to take soft tissue into account such as e.g. the uterus is NOT allowed as this 1418
might take nodes and elective target out of the treated volume. Soft tissue verification (evaluation of the position of uterus) based on 1419
CBCT can be performed, but is not mandatory. With soft tissue verification it is possible to evaluate if the daily uterus position is 1420
significantly different from expected and this knowledge can be used to decide that a new treatment plan would be beneficial. 1421
In case that 3D soft tissue verification imaging and monitoring shows that significant parts of CTVs are repeatedly outside the 95% 1422
isodose volume, the following should be considered: 1423
Additional tattoos at the level of L2 1424
Additional planning CT scan for re-planning 1425
Redefining the ITV, taking the information acquired with CBCT into account. 1426
Adjustment of the PTV margin (see the section on angulation of the pelvis in relation to the lumbar spine. 1427
There is allowance for 10% under dosage in the non-involved uterus as accumulated across all EBRT treatment fractions which 1428
is equivalent to a total dose of 40Gy. Brachytherapy contributes to uterus dose normally by >5-10Gy, and the aim is to deliver a 1429
total of 45Gy EQD2 to the uterus in terms of total EBRT and BT dose (D98). 1430
1431
57
9.8.1 ANGULATION OF THE PELVIS IN RELATION TO THE LUMBAR SPINE 1432
With para aortic radiation, flexing of the thoraco-lumbar spine in relation to the pelvis can be a concern considering the tight PTV 1433
margin. In case of repeated residual misalignment of more than 5mm despite daily correcting to match on bony anatomy the following 1434
procedures should be considered: check if immobilization device is used optimally; consider additional tattoos at the level of L2; 1435
consider an additional planning CT scan; a last step would be to consider to expand the PTV margin in the para-aortic region where the 1436
residual set-up error persists. 1437
9.9 PLANNING AIMS FOR TARGETS AND ORGANS AT RISK 1438
With a prescription dose of 45 Gy to PTV45, and 55-57.5 Gy to PTV-N (#) if applicable, delivered in 25 fractions, the dose volume 1439
constraints for organs at risk (OAR) summarized in table 9.4 need to be met. Note that these OAR constraints are based on the PTV 1440
definition described in chapter 9.2.3 with a 5 mm ITV to PTV margin. 1441
Table 9.4: Summary of planning aims for OAR and target. 1442
Hard dose constraints Soft dose constraints
Targets PTV45 V95% > 95% Dmax<107%*
ITV45 Dmin> 95%
PTV-N(#) D98% > 90% of prescribed LN dose Dmax < 107% of prescribed LN dose
CTV-N(#) D98% > 100% of prescribed LN dose
D50% > 102%
Help contour CTV-HR +10mm Dmax < 103%
OARs Bowel Dmax < 105% (47.3Gy)* When no lymph node boost:
V40Gy < 100cm3**
V30Gy < 350cm3** When lymph node boost or para-aortic irradiation:
V40Gy < 250cm3**
V30Gy < 500cm3** Dmax < 57.5Gy
Sigmoid Dmax < 105% (47.3Gy)* Dmax < 57.5Gy
Bladder Dmax < 105% (47.3Gy)* V40Gy < 75%** V30Gy < 85%** Dmax < 57.5Gy
Rectum Dmax < 105% (47.3Gy)* V40Gy < 85%** V30Gy < 95%** Dmax < 57.5Gy
Spinal cord Dmax < 48Gy
Femoral heads Dmax < 50Gy
Kidney Dmean < 15Gy Dmean < 10Gy
Body Dmax < 107%*
Vagina PIBS-2cm
When vagina not involved: DPIBS-2cm<5Gy
Optional Ovaries <5-8 Gy
Duodenum*** V55<15cm3
*In case that lymph nodes are not boosted, ***Verma J. et al. 2014 1443
**Soft constraints which can be used as optimisation constraints as they are not based on clinical evidence. The constraints are not 1444
supposed to be fulfilled by all patients, but rather by ~70-80% of the patients. 1445
58
9.10 REPORTING OF EBRT PARAMETERS 1446
The following parameters are read out from the treatment planning system and entered into the database: 1447
Volume (nomenclature) Dose and volume parameters
Initial GTV-T (cm3) Volume
Initial HR CTV-T (cm3) Volume
Initial LR CTV-T (cm3) Volume
ITV45 (cm3, Gy) Volume, D98
PTV45 (cm3, Gy) Volume, D98
GTV-N(#) volume (cm3) Volume
CTV-N(#) (Gy) Volume, D98
PTV-N(#) (Gy) D98
Bowel (cm3) V15Gy
Bowel (cm3) V30Gy
Bowel (cm3) V40Gy
Bowel (cm3) V50Gy
Sigmoid (%) V30Gy
Sigmoid (%) V40Gy
Sigmoid (%) V50Gy
Bladder (%) V30Gy
Bladder (%) V40Gy
Bladder (%) V50Gy
Rectum (%) V30Gy
Rectum (%) V40Gy
Rectum (%) V50Gy
Body (cm3)* V43Gy
Body (cm3)* V50Gy
PIBS +2cm (Gy) Point dose
PIBS (Gy) Point dose
PIBS -2cm (Gy) Point dose
*Total volume (including PTV and entire body). Depending on planning system a helper structure might be necessary (e.g. Monaco) 1448
1449
59
10 BRACHYTHERAPY 1450
10.1 INTRODUCTION AND SPECIFIC AIMS FOR BRACHYTHERAPY 1451
Treatment planning and performance of BT is based on the recommendations of the "ICRU 88/GEC ESTRO Report" on "Prescribing, 1452
Recording and Reporting Brachytherapy for Cancer of the Cervix" (ICRU report 88, in press 2015) where the concepts and parameters 1453
for image guided adaptive brachytherapy are systematically described. A detailed understanding of this report is essential for 1454
brachytherapy in EMBRACE II (a brief introduction in target concepts is outlined in chapter 3.2). Reading major parts of this report is 1455
therefore necessary for investigators including patients into the EMBRACE II study. 1456
The specific aims for brachytherapy in Embrace II are: 1457
1. To increase the optimal and safe use of cervix cancer brachytherapy by use of a prospective protocol for dose planning 1458
and prescription for multiple targets and OAR based on the findings from RetroEMBRACE and EMBRACE 1459
2. To increase the use of combined intracavitary and interstitial (IC/IS) application in order to meet the planning aims and 1460
DVH constraints of Embrace II 1461
3. To ensure that the overall treatment time stays below 50 days 1462
4. To maintain and possibly improve a high level of local control in small and well responding tumours 1463
5. To improve local control in large and poor responding tumours through dose escalation by systematic use of combined 1464
IC/IS applications 1465
6. To decrease brachytherapy related morbidity through systematic application of brachytherapy related dose volume 1466
constraints. 1467
7. To reduce vaginal morbidity through dose-de-escalation in the vagina by reduction of vaginal loading in cases with no 1468
vaginal involvement. 1469
1470
10.1.1 OVERALL SCHEDULE FOR EBRT AND BT AND CHEMOTHERAPY 1471
The overall treatment time (OTT), defined from the first external beam fraction to the final external beam or brachytherapy fraction 1472
dose is delivered should be < 50 days. Based on analyses of retro-EMBRACE (Tanderup K. et al. in submission 2015) increase of OTT by 1473
one week is equivalent to de-escalating CTVHR dose by 5 Gy. 1474
Figure 10.1: Examples of overall schedules administering
25 fractions of EBRT with or without simultaneous
integrated lymph node boost (blue bars), 5 courses of
concomitant cisplatin (black bars) and 4 fractions of HDR
brachytherapy (red bars) within an overall treatment
time of 7 weeks (upper panels) or 6 weeks (lower panel).
Analogue scheduling applies for PDR brachytherapy.
60
To obtain maximal tumour regression the treatment should always be initiated with EBRT and concomitant chemotherapy for 4-5 1475
weeks before BT is applied in weeks 6-7 (Figure 10.1, upper panel A). For a small and/or well responding tumour BT may be initiated 1476
already during EBRT to shorten the overall treatment to 5-6 weeks (panel B). In any case every effort should be made to keep the 1477
overall treatment time < 50 days. 1478
If possible it may be advantageous to initiate EBRT and concomitant chemotherapy in the beginning of a week to avoid loss of 2 days in 1479
OTT already during the first weekend. Concomitant chemotherapy given on the first days of the week also theoretically paves the way 1480
for sensitizing more fractions of EBRT in that week, rather than giving chemotherapy on a Friday where the sensitizing effect is expected 1481
to vanish during the weekend. There is limited data on the optimal timing of EBRT and concomitant chemotherapy on the actual day 1482
where it is given. Centres can use their own schedule. However, for some patients it may be optimal to give EBRT in the morning and 1483
concomitant chemotherapy later in the day to avoid problems with an overhydrated and nauseated patient during EBRT. 1484
10.1.2 PRE-APPLICATION TREATMENT PLANNING 1485
In order to arrive at an appropriate brachytherapy application for cervix cancer a pre-planning procedure is essential which allows for 1486
tailoring the application as much as possible to the vaginal anatomy and the tumour spread as it presents at the time of brachytherapy. 1487
This requires in any case a comprehensive clinical gynaecologic examination assessing the vaginal topography and the tumour response 1488
as compared to the situation at diagnosis at the cervix, in the parametria and in the vagina. This should be precisely documented on the 1489
standard gynaecologic template in three orientations including the speculum view. This examination can be supported by volumetric 1490
imaging, preferably MRI, which allows for even more precise documentation of the tumour situation at brachytherapy. Based on this 1491
assessment an individual adaptive CTV-T HR is defined with a certain width, thickness and height. Essential is the relation of these 1492
dimensions of the CTV to the cervical canal, the later location of the tandem, in particular, if the distances to the borders of the later 1493
CTV-T HR are symmetrical or asymmetrical (compare Fig. 10.2-5). Taking these dimensions into account a decision is taken about the 1494
method of application, in particular, if it can be only intracavitary or a combination of intracavitary and interstitial application. The most 1495
precise pre-treatment planning is with a tandem and vaginal applicators in place, which are only inserted for treatment planning (Petric 1496
P. et al. 2009, Fokdal L. et al. 2013). 1497
A basic preplanning procedure must be implemented routinely in gynecologic brachytherapy for a tailored application. For EMBRACE II 1498
application adaptation must be a common procedure in daily clinical practice. Systematic use of combined intracavitary and interstitial 1499
applicators (based on individual mould, ring, ovoids) is a request for appropriate dose adaptation which is dose escalation in particular 1500
for advanced parametrial disease and/or dose sparing in adjacent organs at risk. Continuous further development is necessary based on 1501
clinical and imaging information and corresponding applicator design (Dimopoulos JC. et al. 2006, Jürgenliemk-Schulz IM. et al. 2009, 1502
Kirisits C. et al. 2006). A systematic pre-application planning strategy, including a pre-procedure CTV-T, is considered important for 1503
EMBRACE II to account for the specific clinical situation, the selection and contouring uncertainties in adaptive CTV-T, and the expected 1504
geometrical and dosimetrical uncertainties (Fokdal L. et al. 2013, Petric P. et al. 2009, Tanderup K. et al. 2010). 1505
1506
10.2 APPLICATOR INSERTION FOR BRACHYTHERAPY 1507
Bowel preparation should always be used to ensure an empty rectum and sigmoid colon, which is of particular importance when using 1508
interstitial needles in addition to intracavitary treatment and also for PDR with prolonged stay in bed. Supportive treatment such as low 1509
molecular weight heparin, antibiotics and analgesics are given according to individual patient needs and institutional practice. 1510
Before placement of the BT applicator a clinical assessment of the tumour extension is performed describing tumour dimensions 1511
(width, height and thickness) as well as the possible involvement of parametria, vagina, bladder and rectum. The clinical examination is 1512
documented by drawings by use of the standard clinical diagram (see appendix 22.1). 1513
A Foley catheter is placed in the bladder and 7 ml of diluted contrast medium (e.g. gadolinium or saline) is injected into the balloon 1514
which is suitable to correctly visualize the balloon on MRI. 1515
61
Each participating department should define standard rules for bladder filling which should be followed both during each imaging 1516
procedure (MRI/CT) and the subsequent BT treatments. For HDR this is usually obtained by emptying the bladder and installing a 1517
specified amount of saline in the bladder, whereas for PDR an “open catheter policy” during both imaging and treatment is usually 1518
applied. 1519
Dilatation of the uterine canal can be guided by ultrasound and the depth of the uterine cavity is measured. An MRI compatible 1520
applicator is then chosen depending on the anatomical topography of tumour, uterus, cervix and vagina and placed in close contact 1521
with the tumour and cervix. The choice of the applicator type depends on the individual anatomy and the tumour spread at the time of 1522
brachytherapy. The choice of applicator type (e.g. ring or ovoid type) is up to the decision of each centre. Additional implantation of MR 1523
compatible needles in the parametrium and/or vagina have to be used as appropriate for appropriate target coverage. Vaginal packing 1524
must be performed with gauze to push away the rectum and bladder and to fix the applicator against the cervix. The gauze may be 1525
filled with contrast medium as diluted gadolinium, US gel or saline water to distinguish the packing from the vagina. 1526
The applicator may be fixed to the patient by elastic bandages or similar. External fixation to the surgical table/board should not be 1527
used. Alternatively, an individual mould or other customized procedures may be used for fixation of the applicator according to the 1528
practice of the participating institution. Important is a fixed geometry of the applicator in relation to the target volume. In-vivo 1529
dosimetry by use of detectors can be used according to institutional practice. 1530
The patient is transferred to the MRI scanner to obtain appropriate images with the patient in the supine treatment position. With 1531
sufficient vaginal packing, there is according to available evidence so far no indication of relevant movement of the applicator relative 1532
to the CTV or to adjacent OAR. 1533
1534
10.3 IMAGING FOR BRACHYTHERAPY 1535
The primary imaging modality for brachytherapy treatment planning is MRI for each individual applicator insertion. Additional imaging 1536
may be performed, if possible, also for each fraction in case of fractionated HDR treatments or as a constancy check during a PDR 1537
course if planned in an individual centre. 1538
The first BT fraction has to be planned based on MRI with applicator in situ. Depending on the situation, MRI can be replaced by CT for 1539
succeeding insertions/fractions. Each applicator insertion must be followed by at least one 3D volumetric image (preferably MRI) and 1540
dose planning, while subsequent fractions using the same implant might be applied with the same treatment plan. Only in case of 1541
exceptional circumstances and if the contouring for reporting is based on an MRI performed at a time point close to the first implant 1542
also the first fraction might be planned without MRI with applicator in situ. In these exceptional cases at least one of the subsequent 1543
fractions has to be MRI based then. 1544
To ensure a reliable reconstruction of the applicator the slice thickness of MRI should be ≤ 5 mm with no interslice gap. Sequences 1545
taken parallel to the applicator, i.e. paratransversal, paracoronal and parasagittal (18) are superior to straight transversal, coronal and 1546
sagittal images with regard to both target contouring and applicator reconstruction. Marker wires of plastic with saline or solutions of 1547
CuSO4 can be used to easy the identification of the source channel and determine any rotation of the applicators (Dimopoulos JC. et al. 1548
2012). 1549
Orthogonal X-rays is not required but may be used in the anterior-posterior and lateral projection with radio-opaque guide wires in the 1550
applicator to ensure that the spatial 2D relation between applicator and target and OAR is satisfying. Dose points must be defined 1551
directly in the 3D imaging set used for contouring and treatment planning and should not be defined in 2D on the radiographs (see 1552
below). 1553
1554
1555
62
10.4 APPLICATOR RECONSTRUCTION AND DOSE POINTS FOR OARS 1556
Uncertainties of 4% (k=1) due to applicator reconstruction are assumed when reporting dose parameters for cervix brachytherapy 1557
(Kirisits C. et al. 2014). This uncertainty level can only be reached by an appropriate step-by-step quality assurance program in each 1558
center (Hellebust TP. et al. 2010): 1559
Step 1: The first step is to define the source path (which is subsequent dwell positions of the actual source inside the applicator) in 1560
relation to the applicator. This is usually defined or at least checked during commissioning of applicators and afterloaders. The source 1561
path can be related to the outer dimensions of an applicator or to marker wires or other indicators placed inside the applicator. A usual 1562
way is to perform auto-radiographs to visualize the dwell positions. Such commissioning procedure should result in drawings of the 1563
essential dimensions or even applicator templates which can be integrated into treatment planning systems. 1564
Step 2: The accuracy of applicator reconstruction is depending on the resolution of the 3D image set. Appropriate imaging has to be 1565
performed, either by reducing the slice thickness, by combining different image orientations (e.g. oblique orientations in transverse, 1566
sagittal and coronal) or by using dedicated 3D sequences (e.g. isotropic voxel size). Each department must ensure that the applicator 1567
reconstruction can be performed with an uncertainty of < 2 mm. This includes the overall deviation of the planned dwell position to the 1568
finally realized dwell position on an anatomical situation as visualized on the planning MRI (or CT). This includes deviations due to 1569
source path definition (commissioning), equipment performance (constancy checks) and the reconstruction process in the treatment 1570
planning system. 1571
Step 3: For CT reconstructions library plans or direct reconstruction based on CT, markers may be the optimal solution. For MRI 1572
reconstructions library plans are the optimal method. Fusion of CT to MRI is most often not helpful for applicator reconstruction; as 1573
such fusion techniques have to be based on the already reconstructed applicator in both image modalities. In certain situations the 1574
needle reconstruction on MRI is difficult. CT can then be used in addition to MRI, either to identify the correct needle tips, or even by 1575
registering MRI with CT via the intracavitary applicator and then use CT for needle reconstruction. However, this depends on the 1576
individual settings and MRI can also be sufficient, even for complex implantation geometries. 1577
The dose points for brachytherapy are defined directly in the volumetric imaging study (MRI or CT). In addition, the point of expected 1578
dose in a specific organ may be determined and used for in vivo dosimetry for instance if rectal diodes are used (optional). 1579
The following dose points should be defined directly in the 3D imaging study: 1580
The ICRU bladder point 1581
The ICRU recto-vaginal point 1582
Vaginal point doses at level of sources (lateral at 5 mm) 1583
Lower and mid-vagina doses (PIBS, PIBS ± 2 cm) 1584
Definition of the point A, the recto-vaginal, the bladder and the PIBS reference points on CT and MRI has to be strictly followed 1585
according to the ICRU88/GEC ESTRO report. Point A is strictly related to the applicator. Practically a coordinate system is rotated and 1586
centered to have it aligned to the applicator, with its origin in the intrauterine applicator axis and the z=0 plane at the surface of the 1587
vaginal applicators. When defining the recto-vaginal and bladder reference points the image orientation is essential. Both points are 1588
defined according to the patient coordinate system - on anterior-posterior lines, which are strictly perpendicular to the longitudinal axis 1589
of the patient. The location of the PIBS points is estimated best on sagittal image orientations, again taking into account the image 1590
orientation to define PIBS on a straight anterior-posterior line perpendicular to the patient axis. From PIBS, PIBS+2 and PIBS-2 are 1591
defined via ruler function in the TPS or entering coordinates in a correct adjusted patient coordinate system. 1592
63
Figure 10.2: The recto-vaginal dose point inserted
according to the ICRU/GEC ESTRO report 88 (image
from Kirchheiner K. et al. in submission 2015)
1593
Figure 10.3. Sagittal views showing the vagina at time of EBRT and at brachytherapy with an intracavitary applicator in place. At the 1594
level of the vaginal source, dose points lateral to the rings or ovoids can be defined at 0 mm and 5 mm from the applicator surface. 1595
Three additional points are defined along the central axis of the vagina in the cranio-caudal direction. The PIBS vaginal-dose point was 1596
defined 2 cm posterior from the Posterior-Inferior Border of the pubic symphysis and for BT at the point of this line where it crosses the 1597
applicator tandem. From there, two additional points 2 cm up and down along the vaginal axis, are defined with PIBS+2 representing 1598
the mid of the vagina and PIBS-2 representing the introitus level (Westerveld H. et al. 2013). 1599
1600
64
10.5 CONTOURING FOR BRACHYTHERAPY: OARS, GTVRES, ADAPTIVE CTVHR, CTV IR 1601
Contouring for both tumour and OAR is performed for each insertion/implant of BT applicators by contouring on T2 weighted (para)-1602
transversal MRI sequences in a dedicated 3D brachytherapy dose-planning system according to the GEC ESTRO Recommendations and 1603
the ICRU/GEC ESTRO report 88 (see for GTV and CTV-T chapter 3.2). The MRI based target delineation can be reused by superimposition 1604
in the process of contouring on CT, if for subsequent fractions of brachytherapy only CT can be used with the applicator in place. 1605
To maintain consistent reporting and communication between investigators and the EMBRACE Study Office the protocol for contouring 1606
AND naming of targets and OAR must be followed strictly. 1607
10.5.1 CONTOURING OF ORGANS AT RISK 1608
The following organs are contoured (from at least 2 cm below the IR-CTV to 2 cm above the uterus): 1609
Bladder: Outer bladder wall including the bladder neck 1610
Rectum: Outer rectal wall from the anal sphincter to the transition into the sigmoid 1611
Sigmoid: Outer sigmoid wall from the recto-sigmoid flexure to at least 2 cm above the parametria and the uterus 1612
Bowel loops: Outer contours of loops positioned within 3-4 cm to the uterus and applicator 1613
For cases with significant vaginal involvement it is advised also to contour the urethra separately to be able to assess the dose to this 1614
structure. There is no specific DVH constraint known so far for the urethra. 1615
If the anatomical transition from rectum to sigmoid is immediately in vicinity of the applicator it is advised to move the transition up or 1616
down to avoid that the D2cm3 for one or the other will be too low. 1617
1618
Figure 10.4: The outer contour of bladder (yellow), rectum (brown), sigmoid (orange) and bowel (light green) shown in the sagittal 1619
plane (Petric P. in Viswanathan et al. 2011). 1620
65
1621
1622
Figure 10.5. “Schematic anatomical diagrams (sagittal view) showing two different positions of the vaginal part of the utero-vaginal 1623
applicators, the cervix tumor, the uterus and the reference volumes of OARs in two different patients. The most irradiated-tissue 1624
volumes adjacent to the applicator, i.e., the reference volumes 0.1 cm3, 2 cm3, and 5 cm³ are illustrated for the various adjacent organs 1625
such as bladder (neck), rectum (anus), sigmoid, and small bowel. The two panels show the different locations of the 0.1 cm3 and 2 cm³ 1626
reference volumes in the adjacent OARs (modified from GEC ESTRO Recommendations II, Pötter R. et al. 2006; see also Westerveld H. 1627
et al. 2013). Reference points are indicated for the bladder (ICRU Report 38), the rectum and upper vagina (ICRU Report 38), and the 1628
mid and lower vagina (PIBS ± 2 cm). Figure: Schematic drawing showing the position of the volumes related to the DVH analysis and 1629
with stars the locations of the bladder, recto-vaginal and three PIBS points (PIBS, PIBS+2, PIBS-2). ….” (from ICRU Report 88, figure 6.4) 1630
The points are in a sagittal image containing the intrauterine applicator except the bladder point, which could be in a parallel plane 1631
before or behind this plane, according to the location of the bladder balloon. 1632
1633
10.5.2 CONTOURING OF TARGET VOLUMES 1634
Accurate tumour and target contouring requires that the contouring physician has performed the gynaecological examination that has 1635
to be done prior to insertion of the applicator and that information including clinical drawings from gynaecological examination at 1636
diagnosis as well as MRI at diagnosis and MRI at time of brachytherapy with the applicator in situ are available at the contouring station 1637
(Figure 10.6). 1638
The following targets should be contoured for brachytherapy: 1639
GTVres: Residual (high signal) Gross Tumour Volume of the primary Tumour 1640
CTVHR: Adaptive High Risk Clinical Target Volume of the primary Tumour 1641
CTVIR:: Intermediate Risk Clinical Target Volume of the primary Tumour 1642
The targets are primarily contoured on the para-axial sequence, but para-coronal and sagittal sequences should be inspected during the 1643
process to ensure target consistency also in these sequences. 1644
66
1645
Figure 10.6: MRI at diagnosis (left panels) and at time of brachytherapy with the applicator in situ (right panels). The brachytherapy 1646
targets (blue: GTVres, red: CTVHR, green: CTVIR) are contoured in the para-axial slide (upper right panel) and here inspected for 1647
consistency in the sagittal sequence (lower right panels). The MRI at diagnosis (left panels) is used to identify grey zones and to ensure 1648
that the CTVIR contour fully covers the primary tumour extension. By courtesy of Primoz Petric. 1649
1650
10.6 TREATMENT PLANNING FOR BRACHYTHERAPY 1651
10.6.1 EVIDENCE OBTAINED FROM RETROEMBRACE AND EMBRACE I 1652
The D90 constraints for the CTVHR are based on dose-response curves for retroEMBRACE. In an analysis of 766 cases from EMBRACE in 1653
2014 72% of cases reached a dose of > 85 Gy for this parameter. The same amount of patients reached at least a dose of 67 Gy for the 1654
CTVHR D100. As D100 is not used, a conversion to D98 is based on a dataset of 403 cases from EMBRACE in 2014 where also D98 was 1655
available. Taking into account the ratios of D98 to D90 and D100 for physical dose, and EQD2 conversion for a PDR schedule of 40 1656
pulses and a HDR schedule of 4 fractions resulted in a dose of ~76 Gy for D98. This was the basis to choose 75 Gy as a constraint for D98 1657
CTVHR. Using the same conversion method for the GTV a D100 constraint of 85 Gy is related to 98 Gy for D98, a D100 constraint of 80 Gy 1658
is related to 91 Gy. These values were rounded to 95 Gy and 90 Gy, respectively. The planning aim dose for the CTVIR is based on a 1659
review of clinical practice within EMBRACE and by taking into account the historical French experience. The 60 Gy volume should 1660
encompass as close as possible the CTVIR which can be described by reaching a near minimum dose D98 of 60 Gy. The planning aim 1661
dose for the point A is a safety measure. Conformal adaptation of dose to very small target volumes, probably related to contouring 1662
uncertainties, should not result in too small brachytherapy contributions. The planning aim of 65 Gy, which is based on expert review of 1663
67
the existing practice within EMBRACE, should warn in case of such small brachytherapy dose values. The dose levels proposed as 1664
constraints for OAR are based on analysis from EMBRACE. For the sigmoid/bowel no clinical evidence is available so far to define 1665
constraints by now. However, suggestions for planning aims and prescribed dose are given, with a clear remark that these constraints 1666
are only valid in case subsequent fractions or pulses are always related to the same most exposed volume of this organ. The constraints 1667
have been tested within a database of EMBRACE. While the proposed planning aims for rectum and bladder were achieved already in 1668
~60%, the constraints for the recto-vaginal point were achieved in 53% and for sigmoid in 80%. The limits for prescribed dose were 1669
reached in >90% of cases, except for the recto-vaginal point (84%). 1670
10.6.2 PLANNING AIMS AND DOSE PRESCRIPTION FOR EMBRACE II 1671
The D90 for the CTVHR should be between 90-95 Gy, while D2cm³ for bladder should be below 80 Gy, D2cm³ for rectum below 65 Gy, for 1672
the ICRU vaginal recto-vaginal point dose below 65 Gy, for the D2cm³ for sigmoid/bowel* below 70 Gy and for D98 for the GTV above 95 1673
Gy (planning aim ~ soft constraints). Taking into account the individual patient case and possibilities in application and dose 1674
optimization, deviations of these planning aims are allowed. However, for the vast majority of patients, the D90 for the CTVHR should be 1675
higher than 85 Gy and the D98 for the GTV higher than 90 Gy, while D2cm³ for bladder should be below 90 Gy, D2cm³ for rectum below 75 1676
Gy, the ICRU vaginal recto-vaginal point dose below 75 Gy and the D2cm³ for sigmoid/bowel* below 75 Gy (limits for prescribed dose ~ 1677
hard constraints). Deviations from these constraints are only allowed in special cases with detailed explanation.For OARS there are also 1678
two levels with planning aims 5 - 10 Gy lower than the maximum limits for the prescribed dose. 1679
Table 10.1: Planning aims (soft constraints) and limits for prescribed dose (hard constraints) for treatment planning in Embrace II. The 1680
EQD2 is calculated using /=10 for targets, /=3 for OAR and a repair halftime of 1.5h. The EQD2 include 45 Gy/25 fractions 1681
delivered by EBRT. 1682
1683
* for the sigmoid/bowel structures these dose constraints are valid in case of non-mobile bowel loops resulting in the situation that the 1684
most exposed volume is located at a similar part of the organ 1685
10.6.3 DOSE OPTIMISATION FOR BRACHYTHERAPY 1686
Dose optimisation is performed by optimising the implant geometry, the dwell time distribution and the fractionation. The use of 1687
implant geometries with interstitial needles in addition to an intracavitary applicator is seen essential for unfavourable topography 1688
(either larger target volumes or unfavourable relation between target and OARs). It is assumed that at least 20 % of a representative 1689
cohort of cervical cancer cases needs such implant techniques to fulfil the planning aims and prescription limits. 1690
Target D90 CTVHR
EQD210 D98 CTVHR EQD210
D98 GTVres EQD210
D98 CTVIR
EQD210 Point A EQD210
Planning Aims > 90 Gy
< 95 Gy
> 75 Gy >95 Gy > 60 Gy > 65 Gy
Limits for Prescribed Dose
> 85 Gy - >90 Gy - -
OAR Bladder D2cm³ EQD23
Rectum D2cm³ EQD23
Recto-vaginal point EQD23
Sigmoid D2cm³ EQD23
Bowel D2cm³ EQD23
Planning Aims < 80 Gy < 65 Gy < 65 Gy < 70 Gy* < 70 Gy*
Limits for Prescribed Dose
< 90 Gy < 75 Gy < 75 Gy < 75 Gy* < 75 Gy*
68
10.6.4 INTRACAVITARY TREATMENT PLANS SHOULD BE BASED ON ITERATIVE STEPS 1691
Preferably, a loading resulting in standardized pear shaped isodose distributions normalized to point A should be used as a starting 1692
point for optimisation. This is usually achieved by certain loading patterns in the intrauterine and vaginal applicator parts. In a stepwise 1693
procedure the loading pattern and the dwell times are optimized until the planning aims are fulfilled. The same procedure should be 1694
used in case of combined intracavitary/interstitial application geometries. The loading and dose contribution from the needles is added 1695
to the intracavitary dose distribution. This ensures that the dose levels and dose gradients around the implant geometry stay 1696
comparable to intracavitary plans and not interstitial plans, where each applicator has a similar weighting. This should ensure to avoid 1697
hot spots and cold spots in any areas not directly controlled via dose points or dose-volume relations. The contribution of the TRAK 1698
resulting from the interstitial components to the overall TRAK varies on each situation, but is usually between 5-20 % (Trnkova P. et al. 1699
2009). 1700
10.6.5 VAGINAL DOSE DE-ESCALATION 1701
Recent EMBRACE data demonstrates that vaginal stenosis is correlated to the brachytherapy dose delivered in the upper vagina (ICRU 1702
recto-vaginal point), and there is significant potential to reduce vaginal morbidity by dose de-escalation. Vaginal dose de-escalation can 1703
be performed by decreasing dwell times in ovoid/ring and increasing the loading in tandem/needles. With the use of combined 1704
intracavitary-interstitial applicators, it is possible to increase the width of the 85Gy isodose volume by loading the needles, and it is not 1705
necessary to heavily load the vaginal sources. Furthermore, limited size tumours often do not need extensive vaginal loading in order to 1706
reach a dose of 85Gy EQD2, since they can be reached mainly by loading the tandem (Nkiwane KS. et al. 2013). 1707
Vaginal loading can be monitored by vaginal dose points, vaginal TRAK or by visually evaluating isodose curves. The major priority when 1708
performing vaginal dose de-escalation is to decrease the ICRU recto-vaginal point dose according to the dose planning aim of 65Gy, 1709
since this is based on clinical evidence. 1710
In a multicenter study by Mohamed et al. it was demonstrated that vaginal dose de-escalation could be performed without 1711
compromising target dose. In this study, reduction of the vaginal loading was attempted such that the 140% isodose would be located 1712
as close to or within the applicator at the lateral aspect - as judged from visual inspection. The 140% isodose refers to the physical 1713
fractional dose which corresponds to 85Gy. E.g. for a fractional schedule of 7Gy in 4 fractions, 140% corresponds to 140%*7Gy = 10Gy. 1714
It was possible to reach the 140% vaginal mucosa criteria in around half of the patients. In the same study by Mohamed et al., it was 1715
possible to limit the vaginal TRAK to a mean of 30% which should be compared to typical classical loading patterns (Paris and Fletcher) 1716
of 50%. In at least 75% of the patients, the vaginal track could be reduced to <40%, and the lateral vaginal dose points (5mm depth) 1717
could be reduced to <85Gy EQD2 (total EBRT and BT dose) (Mohamed SM. et al. 2015, in submission). 1718
Table 10.2: Parameters and constraints for vaginal dose control 1719
1720
1721
Aim Priority
ICRU recto-vaginal point dose <65Gy EQD2 (EBRT+BT) Primary
The ratio of vaginal TRAK and total TRAK <30-40% Secondary
Vaginal lateral dose points at 5mm <85Gy EQD2 (EBRT+BT) Secondary
Visual inspection of the 140% isodose Intruding as little as possible into vaginal tissue, and preferentially located within the applicator
Secondary
69
10.6.6 PTV AND DOSE CONFORMALITY CONSIDERATIONS IN RELATION TO BRACHYTHERAPY 1722
Planning Target Volume (PTV-T) assures that the dose prescribed to the CTV-T is actually applied and has been developed within the 1723
frame of external beam radiotherapy (EBRT). The PTV-T margin around the CTV-T takes into account geometric and dosimetric 1724
uncertainties and is considered essential in EBRT. In brachytherapy the dosimetric characteristics with sources inside the target volume, 1725
the variations and the uncertainties are different from those in EBRT. A PTV-T margin in brachytherapy, selected after implantation of 1726
the applicator, may contribute to dose escalation throughout the target. PTV margins should not be used to compensate for 1727
uncertainties in 3D image guided intracavitary brachytherapy (Tanderup K. et al. 2010). This applies to intracavitary and interstitial 1728
brachytherapy in cervix cancer. Internal target motion is considered minimal when the applicator is fixed by an intra-vaginal 1729
tamponade. 1730
However, geometric uncertainties (reconstruction and contouring) may occur, in particular in the longitudinal direction along the 1731
tandem. As margins along the longitudinal axis of the tandem have limited impact on the dose throughout the target, longitudinal 1732
margins along the axis of the tandem maybe used to compensate for these set up variations. Addition of margins orthogonal to the 1733
tandem axis leads to a dose increase throughout the entire target and are therefore not recommended. 1734
When planning the absorbed dose distribution there is no specific aim for target conformality in the cranial direction. Normally a 1735
margin of 1cm above the CTVHR is applied for robustness to uncertainties (see section 10.5 on PTV). The aim is to achieve the planning 1736
aims as close as possible. However, if those planning aims can be reached, the dose to the parts cranial to CTV (if OAR doses are 1737
fullfilled) is not decreased to reach a conformal situation. By this the dose is kept high in a region which is prone to contouring 1738
uncertainties and possible systematic uncertainties in the applicator location (shifting of the applicator in caudal direction) as shown in 1739
figure 10.7. The longitudinal margin can be secured by visual inspection of isodose lines, and it is not required to draw specifically a PTV. 1740
1741
1742
Figure 10.7 ” Longitudinal margins for set up uncertainties in intracavitary image guided adaptive brachytherapy. Margins are added to 1743
compensate for uncertainties only in the longitudinal direction, whereas no margins can be added in the orthogonal direction. 1744
Therefore a PTVHR may be delineated in the cranio-caudal direction. This may also apply within a planning procedure before the 1745
applicator insertion, resulting in a guiding PTV, which may guide the necessary length of the tandem to compensate for set-up 1746
uncertainties”. (from ICRU report 88 fig. 5.17). In EMBRACE II a cranial margin above CTVHR of 1cm is advised when this does not 1747
compromise OAR exposure. 1748
1749
70
10.7 DOSE AND VOLUME RECORDING AND REPORTING 1750
Recording and reporting follows the recommendations of ICRU/GEC ESTRO Report 88, where all parameters included in level 1 and level 1751
2 of the reporting standards are included: The physical doses should be reported to the database NOT the EQD2! 1752
Table 10.3. Reporting of dose and volume parameters for BT (from ICRU 88) 1753
GTVres Volume, D98
CTVHR Volume, D98, D90, D50
CTVIR Volume, D98
GTV N* Near minimum dose (point dose assessment)*
Point A (only when intracavitary) Point dose
Bladder D0.1 cm³, D2 cm³
Rectum D0.1 cm³, D2 cm³
Sigmoid D0.1 cm³, D2 cm³ and assessment of mobility
Bowel D2 cm³ and assessment of mobility
ICRU recto-vaginal point Point dose
ICRU bladder point Point dose
Vaginal dose at level of sources Point dose lateral at 5 mm
Lower and mid-vagina doses PIBS, PIBS ± 2 cm**
TRAK
* Lymph nodes which were pathologic at diagnosis (in case of complete regression at time of BT, a representative dose should be 1754
estimated for the region where the node was). If the node is not covered by the MRI performed for brachytherapy it is assumed that 1755
the dose contribution from brachytherapy to such a node is negligible. 1756
** if PIBS-2cm is outside the MR image object assign a representative dose 1757
1758
1759
71
11 SYSTEMIC TREATMENT 1760
11.1 AIMS FOR CHEMOTHERAPY 1761
To improve systemic and nodal control and to improve survival 1762
To apply systematically simultaneous chemotherapy (minimum 90% of patients who qualify as able to undergo 1763
chemotherapy); 1764
To apply full dose of chemotherapy (5 cycles) in the vast majority of patients (80% of those patients who receive 1765
chemotherapy). 1766
11.2 CONCOMITANT CHEMOTHERAPY 1767
Chemotherapy is given according to the studies reported by Key et al. and Rose et al. (Rose PG. et al. 2011, Keys HM. et al. 1999). 1768
Cisplatin is to be given intravenously at a dose 40 mg/m2 once a week for a total of preferably 5-6 cycles according to institutional 1769
practice. In EMBRACE I para-aortic and distant control was inferior when less than 5 cycles of cisplatinum monotherapy had been 1770
administered. Other chemotherapeutics and schedules might carefully be considered if monotherapy cisplatin cannot be given due to 1771
patient related factors, like co-morbidity or early cisplatinum related morbidity and must be reported. Treatment with Cisplatin should 1772
be withheld at the discretion of the center. Several guidelines on chemo-radiation protocols exist for cisplatin withhold (Rose PG. et al. 1773
2011, Keys HM. et al. 1999, Pearcey R. et al. 2002). Leucocytes and granulocyte numbers are used as constraints for withhold of 1774
cisplatin. Therefore we suggest to use either leucocyte or granulocyte counts as constraints. Guidelines for withhold vary for leucocytes 1775
counts around 2.500 or for granulocytes counts between <1,5 to 1.0 X 109 cell/L. For platelets guidelines for constraints vary 1776
between < 100 to < 50 X 109 cell/L platelets. Cisplatin can be resumed in the next cycle once the blood counts exceed these limits. 1777
The dose of Cisplatin should be reduced to 30 mg/m2 if two consecutive cycles of chemotherapy have been given at dose zero. Cisplatin 1778
dose should also be reduced to 30 mg/m2 in case of febrile leucopoenia. Cisplatin should be totally discontinued if blood tests remain 1779
unacceptable or febrile leucopoenia recurs despite dose reduction. Cisplatin should also be abandoned in case significant auditory 1780
problems (tinnitus, deafness) or neuropathies > grade 2 develops. 1781
Measurement or calculation (Cockroft-Gault) of GFR is performed before treatment and repeated after 3 cycles. Treatment with 1782
Cisplatin is abandoned if GFR < 50 ml/min.Haemoglobin should be monitored during treatment. Corrections by transfusion according to 1783
institutional guidelines are allowed and have to be reported. 1784
Agent dose/day Route Frequency
Cisplatinum 40mg/m2 i.v. in 3 hours Weekly for 5-6 cycles
1785
11.3 ADJUVANT CHEMOTHERAPY 1786
According to poor outcome in high risk patients, in particular for systemic recurrence, there is in some centers a practice to apply 1787
adjuvant chemotherapy, in particular in the high risk patient group with Carboplatin and Taxol as applied in the OUTBACK trial. 1788
Therefore, the EMBRACE II protocol allows for applying this combination in high risk patients based on a center decision. 1789
If decision for adjuvant chemotherapy for the high risk group is made for patients feasible for it, the centre should in general stick to 1790
this choice throughout the whole study inclusion period. Stratification for yes or no adjuvant chemotherapy will be performed for 1791
treatment outcome analysis. 1792
72
Adjuvant chemotherapy should in principal be administered according the protocol of the treating centre. In order to achieve a certain 1793
level of agreement global recommendations should be followed as given in the protocol of the ongoing clinical OUTBACK trial 1794
(https://www.anzgog.org.au/uploads/ANZGOG%20Trial%20-%20Outback.pdf). 1795
Four cycles of adjuvant therapy with carboplatin and paclitaxel should be given at 3 weeks intervals, starting 4 weeks after completion 1796
of all radiotherapy (EBRT and BT). Before starting adjuvant chemotherapy the toxicities of the concomitant chemoradiation should be 1797
resolved to less than grade 2. Doses should be calculated based on patient’s weight at time of start of adjuvant chemotherapy. 1798
Agent dose/day Route Days
Paclitaxel 155 mg/m2 i.v. in 3 hours 1, 22, 43, 64
Carboplatin AUC 5
(calculated AUC)
i.v. in 3 hours 1, 22, 43, 64
Carboplatin dose is to be calculated according to the Calvert formula: 1799
Dose (mg) = target AUC x (GFR +25) 1800
with AUE being area under curve, GFR calculated according to Cockroft-Gault formula. 1801
Maximum carboplatinum dose (mg) = target AUC (mg/ml x min) x 150 ml/min. 1802
Maximum allowed dose of carboplatin is AUC 5 = 750 mg 1803
Pre-treatment neutrophil count should be ≥ 1/5 x 109/L and pre-treatment platelet count ≥ 100 x 109/L. If counts are below these 1804
levels treatment should be postponed for a maximum of 2 weeks. If counts have not resolved after 2 weeks reduced dose levels should 1805
be administered or adjuvant chemotherapy should be omitted. Decisions for dose reduction or omission of adjuvant chemotherapy 1806
cycles because of hematologic or non-hematologic morbidity is in principle left to the decision of the treating centre but should be 1807
preferable follow the recommendations as described in the OUTBACK trial protocol: 1808
(https://www.anzgog.org.au/uploads/ANZGOG%20Trial%20-%20Outback.pdf). 1809
Pre- and post-hydration procedures, the use of anti-emetics and otherwise medication as well as treatment of eventual allergic 1810
reactions are left to the decision of the treating centre. 1811
1812
73
12 OUTCOME ASSESSMENT 1813
Outcome in terms of survival, disease control, morbidity and Quality of Life (QoL) must be assessed prospectively for 5 years by 1814
scheduled follow-up according to this table: 1815
1 1816
1817
1818
1819
1820
2Base Line, 2Week 4 during EBRT, 3At the end of radiotherapy including BT 1821
1822
The results of the follow-up should be reported to the database as soon as possible (preferably on line) but not later than 4 weeks after 1823
the follow-up has taken place. If QoL forms are not returned by the patient 2-3 weeks after a follow-up a new form with request for 1824
response should be send. However, no further request should be send if there is no response. 1825
Unplanned follow-up due to suspicious of recurrence and/or development of morbidity should be performed in the same manner as 1826
regular follow-ups and reported to the database 1827
Gynaecological examination must include recto-vaginal exploration. General anaesthesia is recommended at 3 month and also if a local 1828
recurrence is suspected in order to maximise the possibility for evaluating local tumour control, take biopsies and to reopen vaginal 1829
adherences if present. 1830
MRI of the pelvis and retro-peritoneum should routinely be performed at 3 month and at 12 month after end of radiotherapy. It is 1831
recommended to perform whole body FDG PET-CT as a routine investigation at the 3 months follow-up as well. MRI, CT and/or PET-CT 1832
should be performed according to the clinical needs when a recurrence (local, nodal, systemic) is suspected. Every effort should be 1833
made to confirm recurrences by biopsy. 1834
1835
12.1 ONCOLOGICAL OUTCOME AND SALVAGE TREATMENT 1836
The predictive value of the time/volume response of the primary tumour (GTV-T) during radiotherapy will be assessed by comparing 1837
the volume of GTV-T contoured on MRI for EBRT and on MRI for each BT implant. 1838
The GTV-T response will be measured according to clinical and imaging criteria for residual disease. The dimensions/volumes are 1839
registered in the CRFs. 1840
The investigators categorize in addition according to the following schedule. This is of particular importance for patients with very good 1841
response and to assess the patients with complete and uncertain complete remission. This is an area of much uncertainty and the aim 1842
of EMBRACE II is to have a more precise assessment of GTV volume response in order to build upon this experience further 1843
stratification into risk groups for future trials (both for local and general outcome): 1844
1845
Time Point BL1 W42 End3 3M 6M 9M 12M 18M 24M 30M 36M 48M 60M
Clinical exam. ● ● ● ● ● ● ● ● ● ● ●
Gyn. exam. ● ● ● ● ● ● ● ● ● ● ●
Diagnostic MRI ● ● ●
Morbidity scoring
● ● ● ● ● ● ● ● ● ● ● ● ●
QoL ● ● ● ● ● ● ● ● ● ● ● ● ●
74
Complete remission: CR no residual GTV detectable: no contour
Uncertain complete remission: uCR residual GTV questionable: contour yes or no
Partial remission: residual GTV clearly detectable: contour
Stable disease: no significant change in GTV (+/-10%): contour
Progressive disease: significant GTV increase (>10%) contour
Table 12.1 Categorization of remission (in addition to measurements) 1846
The first evaluation for local control is at 3 month follow-up. If biopsy is performed and confirms that the primary tumour is still present 1847
this will be categorised as persistent local disease. If uncertainty exists at this time point despite MRI and gynaecological examination 1848
which are not resolved by biopsies, PET-CT scan or other measures, then the patients should be followed closely at least with 1849
gynaecological examination and MRI and/or PET-CT at the subsequent follow-ups until the questions has been resolved. The patient will 1850
be categorised as having obtained local control at 3 months, if later follow-up then shows continuous local control. On the other hand if 1851
this does not happen and the tumour eventually progresses this will be categorised as persistent disease at 3 months. Salvage 1852
hysterectomy should be performed when relevant/possible in case of persistent or recurrent local and central disease. 1853
Pathological nodes are numbered consecutively (N1, N2,…N10) at diagnosis. If persistent or recurrent nodal disease is found on imaging 1854
during follow-up bioptical verification should be attempted. The relevant images should then be matched with the pre-treatment scans 1855
to see if these nodes match with already known nodes from time of diagnosis (i.e. N1, N2..N10) or if they represent new nodes. New 1856
nodes should be evaluated with regard to the PTV45 as inside, marginal or outside. Salvage radiotherapy +/- surgical removal of 1857
previously unirradiated nodes should be attempted if there are no signs of systemic recurrences. 1858
Oligometastases in previously unirradiated volume should also be evaluated with regard to the possibility of salvage treatment 1859
(surgery, stereotactic body radiotherapy etc.). 1860
The oncological outcome of intended curative salvage treatment (local, regional, systemic) should be reported in the database. 1861
Palliative treatments are not reported but the vital status should be updated at least quarterly. 1862
In case patients are lost to follow-up as much information as possible should be gathered and reported, e.g. at least the survival status. 1863
1864
12.2 MORBIDITY 1865
Physician assessed morbidity will be scored prospectively with the Common Terminology Criteria for Adverse Events (both CTCAE v3.0 1866
and CTCAE v4.0, NCI 2003 and 2009) on a priori selected, clinical relevant endpoints regarding gastro-intestinal, genito-urinary, vaginal 1867
and several unspecific symptoms (See table above). 1868
Both early morbidity (per definition within the first 90 days after begin of treatment) and late morbidity will be assessed. Early 1869
morbidity will be assessed with a short version of the overall morbidity assessment with selected endpoints. 1870
The morbidity endpoints for EMBRACE 2 were selected after a consensus based on yearly interim comprehensive analyses of the 1871
EMBRACE 1 material, covering inter alia: longitudinal analyses on manifestation pattern of symptoms, evaluation of the open text 1872
75
reports of the EMBRACE 1 database, cross-validation with the patient reported symptoms from the quality of life assessment, literature 1873
research and joint clinical discussions. 1874
Case report forms are available for download at the EMBRACE 2 website. 1875
Analyses: Morbidity outcomes will be analysed if baseline and at least one follow-up assessment have been recorded. Morbidity will be 1876
censored at time of any recurrence (local, nodal, systemic) and baseline morbidity will be taken into account in any analysis in order to 1877
differentiate between tumour-related and treatment-related symptoms. 1878
Endpoints will be evaluated both for the overall organ at risk (bowel, rectum, bladder, vagina etc.) and for individual symptoms with 1879
prevalence rates, crude and actuarial incidences (Kaplan Meier time to event method). For selected endpoints, a dose effect relation 1880
will be investigated based on Cox proportional hazard models; independent risk factors for morbidity will be taken into account by 1881
multivariate modelling. 1882
12.3 QUALITY OF LIFE (QOL) 1883
QoL will be assessed prospectively with the internationally established and validated questionnaires of the European Organization for 1884
Research and Treatment of Cancer (EORTC; http://groups.eortc.be/qol). 1885
The basic module EORTC QLQ-C30 is of general use for all cancer sites and consists of five functional scales (physical, emotional, social, 1886
role and cognitive functioning), a global health status/QoL scale and several symptom scales commonly reported by cancer patients 1887
(Aaronson NK. et al. 1993). The cervical cancer module EORTC QLQ-CX24 covers typical disease and treatment related symptoms and 1888
items regarding sexuality (Greimel E. et al. 2006). In addition, 6 clinically relevant items of the endometrial module EORTC EN-24 will be 1889
added with the permission of the EORTC QoL group (Greimel E. et al. 2011). 1890
All questionnaires are available for download at the EMBRACE 2 website in all translations available. The time points of assessment are 1891
scheduled according to the morbidity assessment. 1892
Analyses: In QoL reports, patients with baseline and at least one additional EORTC QLQ follow up will be included. In patients with local 1893
and/or nodal and/or systemic evidence of disease in follow-up, the EORTC QLQ data will be censored at the time of recurrence. QoL 1894
outcomes will be calculated and linearly transformed according to the scoring manual of the EORTC QoL group; results reported in 1895
mean scores (ranging from 0-100) with standard deviation and/or 95% confidence interval (Fayers PM. et al. 2001). Results will be 1896
analysed regarding differences in subscales over time in EMBRACE 2 patients and differences between the reference general population 1897
and EMBRACE 2 patients. 1898
1899
76
13 TRANSLATIONAL RESEARCH 1900
13.1 PROGNOSTIC MARKERS 1901
Despite the improved loco-regional control with definitive radio(chemo)therapy in high-risk patients, distant metastasis are still 1902
frequent and - in absence of effective systemic therapy options - have a large impact on cancer specific and overall survival. Tumor type 1903
(squamous versus adenocarcinoma), FIGO stage, tumor size and (extent) of lymph node involvement are well-established prognostic 1904
factors for distant metastasis. When considering the inclusion criteria of current ongoing trials that investigate the value of adjuvant 1905
chemotherapy in addition to definitive radio(chemo)therapy, there may be considerable overtreatment. Several promising (epi) genetic 1906
molecular markers (e.g. HPV-type, hypoxia markers, tumor infiltrating lymphocytes) have been identified, but none have been 1907
compared prospectively in a larger patient cohort nor are they currently applied in clinical practice. 1908
The aim of the translational tumour research project is to establish the value of molecular prognostic markers for local and regional 1909
recurrence as well as distant metastasis in relation to well-described clinical and pathological prognostic factors. Better selection of 1910
patients at high risk of distant metastasis or recurrence will allow for a highly personalized treatment approach. While comparing tumor 1911
samples from the primary tumor with that of primary involved lymph nodes and to those at time of recurrence will help understand 1912
which factors contribute to disease progression and therapy resistance. EMBRACE II will include a large cohort of patients treated with a 1913
uniform protocol and therefore offers a unique opportunity to make progress in this field. 1914
Paraffin embedded tumor tissue derived from biopsies of the primary tumor and available lymph node metastasis at the time of 1915
diagnosis will be collected from all consenting patients. 1916
In addition, paraffin embedded tumor tissue derived from biopsies of local and regional recurrences or distant metastasis, if performed, 1917
will be collected. DNA will be extracted and a tissue microarray will be constructed from these paraffin embedded tissue samples, 1918
allowing for high throughput analysis. All study samples will be stored in the patient’s treating center, coded under study number, until 1919
DNA extraction and tissue micro array assembly, which will be done centrally at time of study closure under pseudonymized conditions. 1920
A pilot sub-study is envisioned for collaborating centers with facilities to perform and store snap frozen tumour tissue samples, and 1921
collect blood and serum samples (liquid biopsies). The aim of the sub-study is to apply more advanced techniques in a limited number 1922
of patients as a discovery set for novel markers of tumour sensitivity and response. Based on available evidence at the time of study 1923
closure, a more targeted approach will be undertaken, aiming to validate the most promising markers in the large cohort of patients. 1924
For this validation study, preferably more conventional techniques (i.e. hotspot mutation analysis) will be used, facilitating eventual 1925
broader clinical implementation. 1926
1927
13.2 PREDICTIVE MARKERS FOR RADIOTHERAPY RELATED MORBIDITY 1928
In EMBRACE II treatment related morbidity, both clinician-assessed and patient reported, as well as health related quality of life, will be 1929
assessed prospectively in a large cohort of uniformly treated patients. This offers a unique opportunity for intensive translational 1930
research into the identification of biomarkers for the manifestation of (late) treatment-related morbidity. A sub-study is envisioned for 1931
collaborating centres with the aim to improve future individualisation of follow-up strategies and eventually treatment protocols. For 1932
this, early markers indicative of the individual patient’s risk to develop treatment-induced (late) morbidity will be identified and 1933
characterised. This will also allow the development of pathomechanism-based interventions for the prevention, mitigation or 1934
amelioration of morbidity (“biological morbidity targeting”). 1935
Furthermore, indicators of treatment-related morbidities (morbidity biomarkers), assessed pre- or early within the treatment can 1936
facilitate the selection of patients with a high individual risk for (severe) treatment complications, with whom less toxic treatment 1937
strategies may be discussed with the patient to avoid excessive morbidity and to improve post-treatment HR-QoL. Compared to 1938
77
outcome predicting biomarkers, much less work has been done in this field, particularly in relation to radiation dose/dose distributions 1939
(Bentzen SM. et al. 2010). 1940
Some of the most promising morbidity biomarkers for the associated OAR include: 1941
Urinary bladder – urine: Urothelial degradation products, inflammatory markers, and immune response markers (Gibson RJ. & 1942
Bowen JM. 2011). 1943
Large bowel - faeces: Inflammatory markers, calprotectin and lactoferrin (Hille H. et al. 2009, Varela E. et al. 2009) and immune 1944
response markers (Gibson RJ. & Bowen JM. 2011, Henson CC. & Ang YS. 2012). 1945
Vagina - vaginal smears: Cell morphology, differentiation markers, inflammatory markers, and immune response markers 1946
(Gibson RJ. & Bowen JM. 2011, Shield PW. 1995). 1947
Various OAR - blood: Growth factors (various OAR), immune cells (immune system and others), immune response markers 1948
(epithelia, bone marrow), citrulline (small bowel), other serum proteins (intestine) (Lutgens LC. et al. 2003, Lacombe J. et al. 1949
2011, Chai Y. et al. 2015, Onal C. et al. 2011). 1950
1951
Although many promising morbidity biomarkers have been identified over the years, none has been validated in large datasets, and 1952
none has therefore been entered into routine clinical use. Translational (morbidity) research within EMBRACE II will establish and/or 1953
optimize the respective analytical procedures, in samples from an initial (small) test population of patients. The most promising 1954
candidates for each OAR morbidity endpoint will be defined and the respective analytical procedures will be established in the section 1955
for applied and translational radiobiology (ATRAB) in Vienna. Subsequently these candidates will be analyzed in a larger cohort of 1956
patients from participating centers. Collection and storage of biological samples will be standardized to avoid center effects. 1957
One essential prerequisite for the morbidity biomarker studies is the precise assessment and documentation of early and particularly 1958
late morbidity. This will be standardized within EMBRACE II (see “morbidity and QoL”). 1959
1960
1961
1962
1963
1964
1965
1966
1967
1968
1969
78
14 PATIENT MATERIAL, BENCHMARKING, VALIDATION, EVALUATION AND STATISTICS 1970
14.1 BENCHMARK OF OUTCOME AND TREATMENT RELATED PARAMETERS 1971
EMBRACE aims at improving outcome of locally advanced cervical cancer through well-defined interventions of advanced EBRT 1972
(IMRT/IGRT), IGABT and systematic application of chemotherapy in a limited overall treatment time (section general aims 4.2.1). 1973
EMBRACE II will be benchmarked against the outcome of the retroEMBRACE and EMBRACE cohorts and reports from literature as 1974
appropriate. The benchmark will include evaluation of overall survival, cancer specific survival, local control, pelvic control, nodal 1975
control (regional, para-aortic), distant control, morbidity (various organs and morbidity endpoints), patient reported outcome and 1976
quality of life. The prognostic characteristics of the patient populations may change over time and the evaluation will take into account 1977
major prognostic factors through stratification and/or other statistical methods such as propensity score weighting. The general 1978
hypothesis on survival (section 5.3.1) and the specific hypotheses on specific clinical endpoints (section 5.3.3). will be tested. 1979
Treatment related factors (“interventions” section 4.1) will be benchmarked and compared with those recorded in the EMBRACE and 1980
RetroEMBRACE cohort: target selection, tumor and target volumes, EBRT techniques (IMRT/IGRT) and BT techniques (adaptive 1981
intracavitary/interstitial), irradiated volumes, target doses, organ doses, chemotherapy administration, and OTT. Change of practice 1982
compared with EMBRACE with regard to technique, dose and volume will be quantified, and the specific hypotheses described in 1983
section 5.3.2. will be tested (table 5.1). 1984
The protocol compliance will be evaluated both on the level of the entire EMBRACE II cohort as well as on a centre level. In particular, 1985
the performance with regard to the major EMBRACE II interventions will be monitored: BT technique and dose prescription, reduction 1986
of vaginal loading, utilization of IMRT/VMAT, utilization of daily IGRT and limited margins, EBRT target concepts related to the primary 1987
tumour, EBRT dose prescription and fractionation, selection of elective EBRT target volume, and application of concomitant 1988
chemotherapy. 1989
14.2 VALIDATION OF DOSE AND VOLUME EFFECTS 1990
EMBRACE II validates dose and volume effects as found in RetroEMBRACE and EMBRACE I (section specific aims 4.2.2). In EMBRACE I 1991
and RetroEMBRACE, dose-effect relationships related to the BT high dose regions have been found for different endpoints (section 1992
introduction 3.3). These dose-effect relationships will be validated in the EMBRACE II cohort. 1993
14.3 EXPLORATION AND EVALUATION OF DOSE AND VOLUME EFFECTS 1994
EMBRACE II explores and evaluates dose effect relationships related to intermediate EBRT and BT dose and volume levels in the 1995
EMBRACE II cohort comparable to RetroEMBRACE and EMBRACE I for BT high dose regions. Finally, dose and effects of chemotherapy 1996
administration will be evaluated. 1997
14.4 IDENTIFICATION OF PROGNOSTIC AND PREDICTIVE PARAMETERS 1998
EMBRACE II will test beside dose and volume various prognostic and predictive parameters for disease outcome, morbidity and quality 1999
of life and compare with EMBRACE and literature reports as appropriate. 2000
14.5 STATISTICS 2001
Data will be reported with mean and standard deviation / 95% confidence interval or median and interquartile range, depending on the 2002
distribution. Proportions will be evaluated as number of patients with and without the characteristic and as a percentage. 2003
79
Time-to-event data will be analyzed using the actuarial Kaplan Meier method; time will be calculated with the date of diagnosis as the 2004
starting date and the date of the defined event. Data from patients who had not reached the endpoint at the time of the last follow-up 2005
will be treated as censored observations. 2006
Local control will be defined as absence of disease in the cervix, uterus, upper vagina and parametria on clinical examination, imaging, 2007
and biopsy. Pelvic control will be defined as absence of local and nodal disease within the pelvis. Nodal control will be defined as 2008
absence of nodal disease within the pelvis and within the para-aortic nodes. Systemic control will be defined as absence of any organ 2009
recurrence and extra-pelvic and extra-aortic nodal recurrence. 2010
Overall survival will be defined as death from any cause and cancer specific survival as death from cervical cancer (disease progression 2011
or treatment-related morbidity). 2012
Morbidity outcomes will be analyzed for organs and specific endpoints within one organ if baseline and at least one follow-up 2013
assessment have been recorded. Morbidity will be censored at time of any recurrence (local, nodal, systemic) and baseline morbidity 2014
will be taken into account in any analysis in order to differentiate between tumor-related and treatment-related symptoms. 2015
Serious late morbidity will be defined as grade 3 (severe), 4 (life-threatening) or 5 (death) complications present at or after 91 days 2016
from completion of treatment. Morbidity analyses will also be performed on grade 1 (mild) and grade 2 (moderate) complications. 2017
Endpoints will be evaluated both for the overall organ at risk (bowel, rectum, bladder, vagina etc.) and for individual symptoms with 2018
prevalence rates, crude and actuarial incidences (Kaplan Meier method). 2019
Several a priori chosen, clinically relevant patient-, disease- and treatment characteristics (prognostic and predictive factors) will be 2020
evaluated as risk factors for outcome events in uni- and multivariable analyses (Cox proportional hazards model). Hazard Ratios (HR) 2021
and 95% confidence intervals (CI) will be estimated. 2022
Cox proportional hazards model estimates will be used to evaluate several dose and volume effect relationships with regard to selected 2023
endpoints, such as local control and morbidity. Dose parameters will be normalized to 2Gy per fraction (EQD2) using the linear-2024
quadratic model with α/β ratio of 3Gy. 2025
Advanced modeling studies and studies for comparing various cohorts using advanced statistical methods (e.g. propensity score) are 2026
foreseen. 2027
Significance level will be set 2-sided at 5% and methods to correct for the increased probability of Typ 1 errors of multiple testing will be 2028
applied. All statistical analyses will be performed using the Statistical Package for the Social Sciences IBM SPSS (Armonk, NY: IBM Corp). 2029
2030
2031
2032
80
15 ACCREDITATION, DUMMY RUN, DATA MONITORING, QUALITY ASSURANCE AND CONTINUOUS 2033
EDUCATION 2034
EMBRACE II accreditation includes an evaluation of the current practice of each centre through a “compliance questionnaire” on 2035
brachytherapy, external beam radiotherapy and chemotherapy. Furthermore, participation in a dummy run on contouring, treatment 2036
planning, and reporting is required. These procedures will ensure that the centre has the infrastructure and expertise needed to comply 2037
with the protocol requirements of EMBRACE II. 2038
It is the responsibility of the study coordinators to evaluate and approve participation. Approval requires a successful dummy run with 2039
an individual assessment of the performance of each participating centre. Approval of the institution/investigator must be 2040
accomplished prior to any patient enrolment in the protocol. 2041
There is no formal on site monitoring, but patient files and treatment plans must be kept at least until closure of the protocol and final 2042
analysis of the results is obtained. Continuous quality assurance during the study is projected. The procedure will include a monitoring 2043
of the treatment planning parameters of interest for this study and an overall check of the CRFs. 2044
A continuous education programme focussing on contouring will be set up and will give access to online education throughout the 2045
study period. Continuous education may be extended to include morbidity assessment and scoring. 2046
15.1 COMMITMENT LETTER, COMPLIANCE QUESTIONNAIRE AND PROCESS DOCUMENT 2047
Each institution has to submit a Commitment Letter to the study coordinators. The centres are also required to complete a web based 2048
compliance form which documents the current practice of the centre demonstrating that the centre in question will be able to meet the 2049
requirements of the protocol with regard to number of patients as well as EBRT and brachytherapy treatment techniques. 2050
The compliance criteria are: 2051
• Treatment of >10 patients per year qualifying for enrolment in EMBRACE II 2052
• Both EBRT and BT are performed in the centre 2053
• Routine use of IMRT or VMAT 2054
• Routine use of daily IGRT with bony fusion 2055
• Routine use of MRI guided IGABT with applicator in situ (at least for first fraction) 2056
• Routine use of the combined intracavitary-interstitial technique when needed (~20-50% of patients) 2057
2058
15.2 DUMMY RUN 2059
Based on evaluation of the compliance questionnaire, the study coordinators will decide if the centre is ready to proceed with the 2060
Dummy Run. The Dummy Run will ensure that the contouring and treatment planning is consistent with the protocol requirements. The 2061
Dummy Run will include a training and registration phase as well as submission of contouring and dose planning for evaluation. Based 2062
on this, the study coordinators will evaluate if the centre is ready to participate in EMBRACE II. 2063
2064
81
15.2.1 TRAINING, REGISTRATION, AND SUBMISSION 2065
• Contouring training for EBRT and BT: self-assessment by each physician who will be contouring for EMBRACE II 2066
• EBRT planning exercise: self-assessment by each institution (physicists/physicians) 2067
• Registration of 5 consecutive patients in a registration database within 6 months: self-registration 2068
• Submission of EBRT and BT contours: one set of contours is submitted per institution for evaluation by study co-ordinators 2069
• Submission of an EBRT dose plan: documentation of one case with dose and volume reporting as well as isodose screenshots is 2070
submitted per institution for evaluation by study co-ordinators 2071
Contouring training for BT and EBRT will be available online using the Addenbrooke’s Contouring Tool (ACT). Contouring will be 2072
performed by each physician according to the EMBRACE II guidelines as outlined in chapters 9 and 10. Instructions, case descriptions, 2073
diagnostic information and contouring guidelines will be available online in ACT. Tools for self-assessment of the training contours will 2074
be available. 2075
An EBRT planning exercise will be downloadable from the EMBRACE website for training of dose planning. IMRT or VMAT dose planning 2076
is performed according to the EMBRACE II guidelines in chapter 9. A reporting sheet will be available for DVH reporting and the results 2077
can be compared to an “expert plan”. 2078
When contouring and dose planning training has been performed, the centre can proceed with registration of 5 consecutive patients in 2079
a registration database (within 6 months). The registration database will be a copy of the EMBRACE II database with on-line reporting of 2080
1) Status at diagnosis, 2) Status at brachytherapy and 3) Treatment and DVH parameters. Furthermore, screen dumps of EBRT and BT 2081
contours and dose plans are required, as well as cartoons documenting clinical examination at diagnosis and at BT. 2082
After the registration phase, a final submission of EBRT and BT contouring and dose planning has to be performed through the ACT tool 2083
(one submission per institution). Specific instructions will be available on the EMBRACE web site. 2084
15.2.2 EVALUATION BY STUDY COORDINATORS 2085
After all information is fully available, the study coordinators will evaluate: 2086
• The submitted EBRT and BT contours 2087
• The submitted EBRT plan 2088
• The completed 5 registered patients 2089
Centres already participating in EMBRACE and having accrued at least 25 patients during the whole EMBRACE period are not required 2090
to enter the registration phase of 5 consecutive patients or to complete brachytherapy contouring training. 2091
2092
15.3 DATA MONITORING 2093
Continuous data monitoring throughout the study will be based on reviewing of data reporting, clinical cartoons and 2094
contouring/treatment planning screen dumps. The data monitoring will be performed by the EMBRACE II study office. 2095
A committee for patient safety and data monitoring will be established consisting of representative(s) from radiation oncology, medical 2096
physics and statistics as appropriate. This committee will meet regularly in large intervals to check the relevant respective issues in the 2097
on-going EMBRACE II study. 2098
82
15.4 CONTINUOUS EDUCATION 2099
Based on ACT, cases will be available for continuous training along the same principles of the dummy run. Annual contouring workshops 2100
will be performed at the annual EMBRACE meetings. MDs who are not attending the annual EMBRACE meeting must perform the 2101
annual contouring remotely. 2102
2103
2104
83
16 PATIENT ENROLLMENT PROCEDURE 2105
Patients’ registration will only be accepted from authorized investigators in the Vienna study office. A patient can be registered after 2106
verification of eligibility by the EMBRACE 2 study office according to the registration form, which includes details on inclusion and 2107
exclusion criteria. In addition, the following information must be provided: 2108
• Patients’ centre ID (made up of the centres’ acronym and the following patient number) 2109
• Patients’ initials 2110
• Patients’ birthday 2111
• Date of scheduled treatment start 2112
If the patient is included in the study, a number will be allocated to the patient (patient sequential identification number). This number 2113
has to be recorded by the investigator. For future communication between the investigator and the EMBRACE 2 database or the study 2114
coordinators, the patients’ centre ID should be used. After successful registration of a patient, the investigator informs the centre that 2115
the data of this patient can be entered in the database. The registration form will be saved electronically by the study office. 2116
Patients must be registered and accepted before any treatment procedures are initiated. 2117
2118
2119
84
17 CASE RECORD FORMS, PROCEDURES FOR DATA COLLECTION, EMBRACE II DATABASE 2120
Patient data will be collected by web based CRF system. The CRFs must be completed and reported according to the time table below. 2121
It is the responsibility of the investigator to check that all CRFs are completely, correctly and timely filled out. 2122
The following CRFs will be used: 2123
Registration Form: To be reported before treatment. 2124
Status at diagnosis Form: To be reported at start of treatment 2125
Base Line Morbidity Form: To be reported at start of treatment 2126
Status at BT Form: To be reported within 4 weeks after treatment completion 2127
Treatment and DVH Form: To be reported within 4 weeks after treatment completion. 2128
Follow-up Form: To be completed within 4 weeks after each regular follow-up. Visits not scheduled should also be reported 2129
within 4 weeks if they concern an event of interest such as recurrence or morbidity 2130
Vital status Form: In case of any event, this part should be updated frequently. 2131
Off study Form: Should be reported within 4 weeks after the off-study occurs. 2132
Curative salvage treatment Form: should be reported within 4 weeks after salvage treatment completion. 2133
After completion of a CRF, a hard copy should be kept in the investigators own patient study file The patient study file is a patient 2134
specific portfolio including a paper copy of the registered CRF data for each patient. 2135
At the EMBRACE 2 website the study protocol, appendices, quality of life questionnaires, patient information folders and any other 2136
pertinent information in relation to the study will be available. 2137
The EMBRACE 2 database will be placed at the Aarhus University Hospital, Denmark. The Danish Board of Registry has approved the 2138
database (pending). Access to the database can be gained through the EMBRACE 2 website, by providing a valid username and 2139
password. Entering of all data will be carried out over the Internet using a standard web-browser. 2140
All data will be encrypted before transmission. A number of validation procedures will be installed in order to ensure a high data 2141
quality. There will be sent out reminders of all follow-up visits and examinations, and data from these will also be entered via the 2142
Internet. 2143
Each centre will be able to log on to the database via the EMBRACE 2 website at any time in order to see descriptive data and number 2144
of included patients for own centre as well as for the entire study population. The database will allow for data extraction in Microsoft 2145
Windows Excel and the Statistical Package for the Social Sciences IBM SPSS (Armonk, NY: IBM Corp). 2146
2147
85
18 ETHICAL CONSIDERATIONS 2148
18.1 PATIENT PROTECTION 2149
This study will be conducted in agreement with the Declaration of Helsinki. The protocol has been written, and the study will be 2150
conducted according to the ICH Harmonized Tripartite Guideline for Good Clinical Practice. The protocol will be approved by the local 2151
Research Ethics Committee in accordance with national guidelines and legislation in the participating centres. 2152
18.2 SUBJECT IDENTIFICATION 2153
To ensure patient privacy, the name of the patient will not be asked for nor recorded at the Study Office. A sequential identification 2154
number will be automatically attributed to each patient registered in the trial. This number will identify the patient and must be 2155
included on all case report forms. In order to avoid identification errors, patient’s initials (maximum of 4 letters) and date of birth and 2156
local chart number (if available) will also be recorded, only on the registration form. 2157
18.3 INFORMED CONSENT 2158
Patient information forms will be produced in all the relevant languages, an English version is included as Appendix 10. All patients will 2159
be informed by the radiation oncologist of the aims and registration process of the study, the possible adverse events, the procedures 2160
and possible hazards to which they will be exposed. The radiation oncologist will hand out the written patient information form, and 2161
before deciding to participate, the patient will be offered enough time for consideration the study. 2162
The consent form will include study participation and subject registration, processing and recording of data, participation to quality of 2163
life investigation and collection and storage of a paraffin embedded tumour tissue sample under study code for future research. 2164
Patients will be informed as to the strict confidentiality of their patient data, but that their medical records may be reviewed for study 2165
purposes by authorized individuals other than their treating physician. 2166
It will be emphasized that the participation is voluntary and that the patient is allowed to refuse further participation in the protocol 2167
whenever she wants. This will not prejudice the patient’s subsequent care. Documented written informed consent must be obtained for 2168
all patients included in the study before they are registered at the Study Office. This must be done in accordance with the national and 2169
local regulatory requirements. 2170
For European Union member states, the informed consent procedure must conform to the ICH guidelines on Good Clinical Practice. This 2171
implies that “the written informed consent form should be signed and personally dated by the patient or by the patient’s legally 2172
acceptable representative”. 2173
18.4 ADVANTAGES AND DISADVANTAGE FOR THE PATIENTS 2174
The radiation oncologist will inform the patients about the possible risks and side effects connected to the involved treatments. At 2175
present the standard treatment for patients with locally advanced cervical cancer is EBRT, concurrent chemotherapy with Cisplatin and 2176
brachytherapy. Although these same treatment modalities will be used, EMBRACE II aims are to implement an image guided risk 2177
adapted dose and volume prescription protocol according to interventions specified in chapter 4. All or some of these advanced 2178
technological interventions will be implemented as standard treatment in participating centres, but there may be deviations in the 2179
extent to which the standard treatment differs from the study protocol per participating institution. Nonetheless, it is expected that 2180
minor deviations between the study protocol and the standard treatment in a centre will not alter the chance of tumour control and 2181
treatment related morbidity for a given individual patient. The written patient information should be adapted if necessary to 2182
accommodate the institutional standard treatment policy and needs subsequent approval by the local ethics committee. 2183
86
Advantages of study participation include external review and quality assurance of the treatment planning and execution, and 2184
knowledge that the individual patient data will contribute to the understanding and future improvement of treatment for locally 2185
advanced cervical cancer. A possible disadvantage of study participation may be the additional time involved in filling out quality of life 2186
questionnaires. 2187
2188
19 PUBLICATION OF DATA 2189
1. The major authors of a manuscript consist of the core research group, which substantially prepared and performed the 2190
research in agreement with the coordinators of the EMBRACE 2 study and the EMBRACE 2 research group. It usually covers the 2191
first author as major contributing scientist, 1-2 active co-workers and 1-2 supervising seniors, according to input. 2192
2193
2. The coordinators of the EMBRACE 2 study and the EMBRACE 2 research group are appropriately represented (minimum 2 2194
persons: Richard Pötter, Kari Tanderup, Jacob Lindegaard, Christian Kirisits). 2195
2196
3. The principle investigators of the centers, who contributed the majority of patients, are listed as co-authors. The principal 2197
investigator (PI) may indicate another person from the institution to replace him or her, if appropriate. This co-authorship 2198
should be minimum 5 centers in addition to Vienna and Aarhus (as represented by the EMBRACE 2 coordinators). The total 2199
number of co-authors based on patient numbers depends on the individual journals requirements. 2200
2201
If manuscripts cover certain sub-cohorts of the overall EMBRACE 2 patients recruited, the number of patients for the specific 2202
analysis of the manuscript is calculated per center, a ranking of the centers is performed according to these numbers. 2203
2204
4. Some journals allow for inclusion of a 'collaborative group', with associated names, which may even be tagged in PubMed. If 2205
possible, such a 'collaborative group' should be included. The number of collaborators should be graduated, according to the 2206
overall recruiting rate of the center: the PI and 1-2 persons designated by the PI (one physicist as appropriate). 2207
2208
20 STUDY OFFICE, STUDY COORDINATORS, STUDY STRUCTURE, COMMUNICATION 2209
The overall collection of all data and all follow-up for all EMBRACE II patients (e.g. CRFs) remains located in Vienna and is done by the 2210
study office (including follow-up of EMBRACE I). The infrastructure of the study office and the communication with centres follows the 2211
experience as gained in EMBRACE. E.g. the weekly EMBRACE meeting in Vienna (about 90 minutes) with review of cases and 2212
participation of study office, medical physicists, radiation oncologists, clinical and research fellows is to be continued. Regular review of 2213
cases will require as in EMBRACE I about 0.5 academic FTE. 2214
In addition, the responsibilities for guiding the brachytherapy and the EBRT branch of EMBRACE II are shared: Vienna will guide the 2215
brachytherapy part and Aarhus the EBRT part. 2216
In addition, there will be one regional centre in Utrecht, which takes the responsibility for guiding all centres in the Netherlands in close 2217
cooperation with Vienna and Aarhus. 2218
2219
2220
87
20.1 STUDY-OFFICE EMBRACE II VIENNA (AT PRESENT: 09/2015): 2221
Ian Dilworth (0.5 FTE), Thomas Liederer (0.5 FTE), Eva Weisz (1.0 FTE), academic position (0.5 FTE) 2222
Department of Radiotherapy, Medical University of Vienna, Vienna, Austria 2223
Telephone: +43 1 40 400 2720; E-mail: @akhwien.at 2224
Aarhus-office: 0.5 FTE academic position 2225
2226
20.2 STUDY COORDINATION: 2227
Principal Investigator: 2228
Richard Pötter, Vienna, Austria: [email protected] 2229
2230
Overall coordinators: 2231
Richard Pötter, Vienna, Austria: [email protected] (overall and BT) 2232
Kari Tanderup, Aarhus, Denmark: [email protected] (overall and EBRT) 2233
Christian Kirisits, Vienna, Austria: [email protected] (overall and BT) 2234
Jacob Lindegaard, Aarhus, Denmark: [email protected] (overall and EBRT) 2235
2236
Regional coordinators in the Netherlands: 2237
Ina Juergenliemk-Schulz, Utrecht (for all participating centres in the Netherlands) 2238
Astrid de Leeuw, Utrecht (for all participating centres in the Netherlands 2239
2240
Continuous Education: 2241
Li Tee Tan, Cambridge University 2242
2243
Senior advisors: 2244
Christine Haie-Meder ([email protected]), Erik Van Limbergen ([email protected]) 2245
2246
Statistician: 2247
NN, Vienna 2248
Søren Møller Bentzen, Maryland, Baltimore, USA ([email protected]) 2249
2250
Communication 2251
All coordinators, the senior advisors and the study secretariat communicate regularly (at least twice per year) on relevant questions of 2252
the EMBRACE study and take joint decisions. 2253
88
Each year an annual meeting is held, where the current activities are reported, discussed and future developments discussed and 2254
decided (following the annual EMBRACE meetings, which took place from 2008-2015 in Brussels (2008) and then in Vienna). All 2255
participating centres are invited for this meeting, including all centres which participated in EMBRACE I. 2256
This meeting forms the body of the study committee: one member of each participating centre, all coordinators, senior advisors, 2257
statistician, study office 2258
The major form of continuous communication is through internet, direct e-mailing and the EMBRACE webpage which has an open 2259
access and a password protected access part. 2260
2261
21 EMBRACE RESEARCH GROUP 2262
In order to take advantage of the large prospective collection of data as established in EMBRACE (and RetroEMBRACE, >2000 patients 2263
with cervix cancer) a multi-disciplinary EMBRACE Research Group has been established in 12/2012. Structures and Principles and 2264
Responsibilities for Research have been set up. Regular physical meetings have been held in addition to research visits through 2265
researchers in particular going to Vienna, Aarhus and Utrecht and additional much internet communication. 2266
Each centre participating in EMBRACE can also participate in the EMBRACE Research Group according to possibilities of the person 2267
interested and the respective centre. On request, also fellows not working in EMBRACE centres can join this Research Group which has 2268
been successful so far in several cases. 2269
The aim of this EMBRACE research group is to build up a large scientific body of clinical evidence based on the large database of 2270
EMBRACE, RetroEMBRACE and the upcoming EMBRACE II study. The topics of research are widespread and related to the whole field of 2271
areas investigated in the EMBRACE studies. So far, 13 publications on various aspects of EMBRACE and RetroEMBRACE could be 2272
published in leading international journals and 4 more are in the submission process. This ongoing process is planned to be followed 2273
and extended in parallel to the implementation of EMBRACE II and will benefit from the maturation of data from EMBRACE I and the 2274
upcoming data of EMBRACE II. 2275
The coordination of this EMBRACE research group is the group of coordinators of the EMBRACE I and II studies (n=6) with the principal 2276
coordinators Kari Tanderup and Richard Pötter. 2277
So far, there is only limited specific sponsoring for this EMBRACE Research Group (travel and accommodation support for group 2278
meetings). 2279
2280
89
22 APPENDICES 2281
22.1 APPENDIX 1 STANDARD CLINICAL DIAGRAM 2282
# 2283
2284
90
Clinical drawings have traditionally been used to depict the extent of disease based on clinical examination. Tumour that is visible 2285
or palpable is drawn manually, usually on paper templates. With the advent of image-guided brachytherapy in cervical cancer, an 2286
argument can be made to also incorporate disease findings from imaging examinations into these “clinical drawings”. 2287
We aim to develop standarized methods for the creation of these clinical drawings, that would hopefully, eventually, lead to some 2288
level of standardization of clinical drawings across different physicians, across different centres, across time, and ultimately, across 2289
multiple tumour sites as well. 2290
“At Diagnosis” or “At Brachytherapy” should be marked on each drawing. Treatment received to date, including any external beam 2291
radiotherapy (EBRT) delivered to date, should be noted. 2292
Four different views or planes are illustrated: Specular, Axial, Coronal, and Sagittal. Dotted lines of the vagina represent a virtual 2293
division in thirds. Dotted lines in the parametria represent a border between the proximal and distal half of the parametria. A pink 2294
line in the coronal view represents uterine artery. 2295
Tumour dimensions: height (h), width (w), and thickness (t) should be documented. Height, defined on the sagittal view, is 2296
measured along the long axis of the uterus. Thickness, defined on the sagittal view, is measured perpendicular to the height. Width, 2297
measured on the axial view, represents the greatest lateral diameter. Vaginal extension of tumour is specified separately. 2298
The date of the evaluation should be recorded. The drawing should be signed. 2299
Manual colour drawing: There are three basic options for the drawing of uniform and reproducible universal clinical drawings. A 2300
first option utilizes coloured marker pens and a colour legend. Four different, specific colours are used. In addition, tumour can be 2301
identified as exophytic in nature by changing the border as outlined in the legend. There are certain advantages to coloured marker 2302
approach, such as straightforward and quick implementation, and immediately recognizable distinctions of different anatomical 2303
areas of involvement. However, the incorporation of up to four specifically coloured markers into routine clinical practice in clinics 2304
and operating rooms may be a challenge to do consistently. Ensuring the consistent availability of the markers in multiple work 2305
environments, with multiple caregivers, may not be practical. 2306
Manual line drawing: A second option uses a legend that requires only a single pen to convey the same amount of information. 2307
Different anatomical areas of involvement are demonstrated using simple line patterns, with a specific pattern for each anatomical 2308
site according to the legend. Again, any exophytic tumour can be delineated with a special border. Unlike the colour approach, 2309
consistent availability of a pen at any location or with any caregiver should not be an issue. A drawback is that the drawings may 2310
appear less readily discernible. However, after a brief learning curve, practioners should be able to draw and read such drawings 2311
with ease. This approach seems the most practical and reliable, and could be adopted widely. 2312
Electronic drawing: Finally, a third option involves a computer-based method to create the clinical drawings. This method involves 2313
electronic versions of the colour or background lines templates, with electronically modifiable tumour cartoons. The cartoons can 2314
be modified for the individual patient by way of a Powerpoint© type of application, using relatively simple tools (Figures 3, 4). 2315
Clinical drawings can be stored and transmitted electronically. Drawings for physical medical chart record-keeping would have to 2316
be printed. Advantages of an electronic approach include the consistency and clarity of the drawings produced. In addition, the 2317
electronic format facilitates the storage, access, and distribution of the drawings. Electronic templates could be made available on 2318
the internet for clinical use. However, logistical issues such as the availability of a local computer with the appropriate software, the 2319
availability of a local (colour) printer for generation of hard copies, and the clinician’s familiarity with the software tools needed, 2320
may preclude this electronic method’s widespread adoption. 2321
Electronical drawing tools will be available for download at the website. 2322
2323
2324
91
22.2 APPENDIX 2 GYN GEC ESTRO RECOMMENDATIONS I-IV, ICRU 88 2325
2326 Haie-Meder C, Pötter R, Van Limbergen E, Briot E, De Brabandere M, Dimopoulos J, Dumas I, Hellebust TP, Kirisits C, Lang S, Muschitz 2327 S, Nevinson J, Nulens A, Petrow P, Wachter-Gerstner N; Gynaecological (GYN) GEC-ESTRO Working Group. Recommendations from 2328 Gynaecological (GYN) GEC-ESTRO Working Group (I): concepts and terms in 3D image based 3D treatment planning in cervix cancer 2329 brachytherapy with emphasis on MRI assessment of GTV and CTV. Radiother Oncol. 2005 Mar;74(3):235-45. Review. 2330 2331 Abstract 2332 2333 BACKGROUND AND PURPOSE: Brachytherapy (BT) plays a crucial role in the management of invasive cervix cancer from stage I to IV. 2334 Intracavitary techniques are based on afterloading devices, with different types of applicators. CT and/or MRI compatible applicators 2335 allow a sectional image based approach with a better assessment of gross tumour volume (GTV) and definition and delineation of 2336 target volume (CTV) compared to traditional approaches. Accurate and reproducible delineation of GTV, CTV and PTV, as well as of 2337 critical organs has a direct impact on BT treatment planning, especially if it is possible to adapt the pear-shape isodose by optimisation 2338 using DVH analysis. When introducing a 3D image based approach for GTV and CTV assessment, there is a need for a common language 2339 to describe the concepts and to define the terms which are to be used. 2340 METHODS: In 2000, GEC-ESTRO decided to support 3D imaging based 3D treatment planning approach in cervix cancer BT with the 2341 creation of a Working Group. The task was to describe basic concepts and terms and to work out a terminology enabling various groups 2342 working in this advanced field to use a common language. The recommendations described in this report were proposed based on 2343 clinical experience and dosimetric concepts of different institutions (IGR, Leuven, Vienna) and were stepwise validated against the 2344 background of different clinical experience. 2345 CONCLUSIONS: As GTV and CTV for BT change significantly during treatment, time frame for assessment of GTV and CTV for BT is 2346 specified in this report: at time of diagnosis GTV(D), CTV(D) and at time of BT GTV(B), CTV(B). Furthermore, CTV for BT is defined related 2347 to risk for recurrence: high risk CTV and intermediate risk CTV. Beside verbal descriptions detailed examples are given, partly in form of 2348 schematic drawings. 2349 2350 2351 Pötter R, Haie-Meder C, Van Limbergen E, Barillot I, De Brabandere M, Dimopoulos J, Dumas I, Erickson B, Lang S, Nulens A, Petrow 2352 P, Rownd J, Kirisits C; GEC ESTRO Working Group. Recommendations from gynaecological (GYN) GEC ESTRO working group (II): 2353 concepts and terms in 3D image-based treatment planning in cervix cancer brachytherapy-3D dose volume parameters and aspects 2354 of 3D image-based anatomy, radiation physics, radiobiology. Radiother Oncol. 2006 Jan;78(1):67-77. 2355 2356 Abstract 2357 2358 The second part of the GYN GEC ESTRO working group recommendations is focused on 3D dose-volume parameters for brachytherapy 2359 of cervical carcinoma. Methods and parameters have been developed and validated from dosimetric, imaging and clinical experience 2360 from different institutions (University of Vienna, IGR Paris, University of Leuven). Cumulative dose volume histograms (DVH) are 2361 recommended for evaluation of the complex dose heterogeneity. DVH parameters for GTV, HR CTV and IR CTV are the minimum dose 2362 delivered to 90 and 100% of the respective volume: D90, D100. The volume, which is enclosed by 150 or 200% of the prescribed dose 2363 (V150, V200), is recommended for overall assessment of high dose volumes. V100 is recommended for quality assessment only within a 2364 given treatment schedule. For Organs at Risk (OAR) the minimum dose in the most irradiated tissue volume is recommended for 2365 reporting: 0.1, 1, and 2 cm3; optional 5 and 10 cm3. Underlying assumptions are: full dose of external beam therapy in the volume of 2366 interest, identical location during fractionated brachytherapy, contiguous volumes and contouring of organ walls for >2 cm3. Dose 2367 values are reported as absorbed dose and also taking into account different dose rates. The linear-quadratic radiobiological model-2368 equivalent dose (EQD2)-is applied for brachytherapy and is also used for calculating dose from external beam therapy. This formalism 2369 allows systematic assessment within one patient, one centre and comparison between different centres with analysis of dose volume 2370 relations for GTV, CTV, and OAR. Recommendations for the transition period from traditional to 3D image-based cervix cancer 2371 brachytherapy are formulated. Supplementary data (available in the electronic version of this paper) deals with aspects of 3D imaging, 2372 radiation physics, radiation biology, dose at reference points and dimensions and volumes for the GTV and CTV (adding to [Haie-Meder 2373 C, Pötter R, Van Limbergen E et al. Recommendations from Gynaecological (GYN) GEC ESTRO Working Group (I): concepts and terms in 2374 3D image-based 3D treatment planning in cervix cancer brachytherapy with emphasis on MRI assessment of GTV and CTV. Radiother 2375 Oncol 2005;74:235-245]). It is expected that the therapeutic ratio including target coverage and sparing of organs at risk can be 2376 significantly improved, if radiation dose is prescribed to a 3D image-based CTV taking into account dose volume constraints for OAR. 2377 However, prospective use of these recommendations in the clinical context is warranted, to further explore and develop the potential 2378 of 3D image-based cervix cancer brachytherapy. 2379
92
Hellebust TP, Kirisits C, Berger D, Pérez-Calatayud J, De Brabandere M, De Leeuw A, Dumas I, Hudej R, Lowe G, Wills R, Tanderup K; 2380 Gynaecological (GYN) GEC-ESTRO Working Group. Recommendations from Gynaecological (GYN) GEC-ESTRO Working Group: 2381 considerations and pitfalls in commissioning and applicator reconstruction in 3D image-based treatment planning of cervix cancer 2382 brachytherapy. Radiother Oncol. 2010 Aug;96(2):153-60. 2383 2384 Abstract 2385 2386 Image-guided brachytherapy in cervical cancer is increasingly replacing X-ray based dose planning. In image-guided brachytherapy the 2387 geometry of the applicator is extracted from the patient 3D images and introduced into the treatment planning system; a process 2388 referred to as applicator reconstruction. Due to the steep brachytherapy dose gradients, reconstruction errors can lead to major dose 2389 deviations in target and organs at risk. Appropriate applicator commissioning and reconstruction methods must be implemented in 2390 order to minimise uncertainties and to avoid accidental errors. Applicator commissioning verifies the location of source positions in 2391 relation to the applicator by using auto-radiography and imaging. Sectional imaging can be utilised in the process, with CT imaging being 2392 the optimal modality. The results from the commissioning process can be stored as library applicators. The importance of proper 2393 commissioning is underlined by the fact that errors in library files result in systematic errors for clinical treatment plans. While the 2394 source channel is well visualised in CT images, applicator reconstruction is more challenging when using MR images. Availability of 2395 commercial dummy sources for MRI is limited, and image artifacts may occur with titanium applicators. The choice of MR sequence is 2396 essential for optimal visualisation of the applicator. Para-transverse imaging (oriented according to the applicator) with small slice 2397 thickness (< or =5 mm) is recommended or alternatively 3D MR sequences with isotropic voxel sizes. Preferably, contouring and 2398 reconstruction should be performed in the same image series in order to avoid fusion uncertainties. Clear and correct strategies for the 2399 applicator reconstruction will ensure that reconstruction uncertainties have limited impact on the delivered dose. Under well-2400 controlled circumstances the reconstruction uncertainties are in general smaller than other brachytherapy uncertainties such as 2401 contouring and organ movement. 2402 2403 Dimopoulos JC, Petrow P, Tanderup K, Petric P, Berger D, Kirisits C, Pedersen EM, van Limbergen E, Haie-Meder C, Pötter R. 2404 Recommendations from Gynaecological (GYN) GEC-ESTRO Working Group (IV): Basic principles and parameters for MR imaging 2405 within the frame of image based adaptive cervix cancer brachytherapy. Radiother Oncol. 2012 Apr;103(1):113-22. 2406 2407 Abstract 2408
The GYN GEC-ESTRO working group issued three parts of recommendations and highlighted the pivotal role of MRI for the successful 2409 implementation of 3D image-based cervical cancer brachytherapy (BT). The main advantage of MRI as an imaging modality is its 2410 superior soft tissue depiction quality. To exploit the full potential of MRI for the better ability of the radiation oncologist to make the 2411 appropriate choice for the BT application technique and to accurately define the target volumes and the organs at risk, certain MR 2412 imaging criteria have to be fulfilled. Technical requirements, patient preparation, as well as image acquisition protocols have to be 2413 tailored to the needs of 3D image-based BT. The present recommendation is focused on the general principles of MR imaging for 3D 2414 image-based BT. Methods and parameters have been developed and progressively validated from clinical experience from different 2415 institutions (IGR, Universities of Vienna, Leuven, Aarhus and Ljubljana) and successfully applied during expert meetings, contouring 2416 workshops, as well as within clinical and interobserver studies. It is useful to perform pelvic MRI scanning prior to radiotherapy ("Pre-2417 RT-MRI examination") and at the time of BT ("BT MRI examination") with one MR imager. Both low and high-field imagers, as well as 2418 both open and close magnet configurations conform to the requirements of 3D image-based cervical cancer BT. Multiplanar 2419 (transversal, sagittal, coronal and oblique image orientation) T2-weighted images obtained with pelvic surface coils are considered as 2420 the golden standard for visualisation of the tumour and the critical organs. The use of complementary MRI sequences (e.g. contrast-2421 enhanced T1-weighted or 3D isotropic MRI sequences) is optional. Patient preparation has to be adapted to the needs of BT 2422 intervention and MR imaging. It is recommended to visualise and interpret the MR images on dedicated DICOM-viewer workstations, 2423 which should also assist the contouring procedure. Choice of imaging parameters and BT equipment is made after taking into account 2424 aspects of interaction between imaging and applicator reconstruction, as well as those between imaging, geometry and dose 2425 calculation. In a prospective clinical context, to implement 3D image-based cervical cancer brachytherapy and to take advantage of its 2426 full potential, it is essential to successfully meet the MR imaging criteria described in the present recommendations of the GYN GEC-2427 ESTRO working group 2428
2429
93
22.3 APPENDIX 3. COMPLIANCE QUESTIONNAIRE 2430
2431
Aims for EMBRACE II
# patients Number of cervix cancer patients treated in your institution with radical radiotherapy in the past 12 months (calendar year or year to date)
(IMPORTANT: indicate only the number of patients treated with BOTH EBRT and BT in your institution)
Answer category:
Indicate number
U Estimated number of patients to be enrolled in EMBRACE II per year
Answer category:
Indicate number
Above 10 pts per year
Treatment planning scan EBRT
Which imaging do you perform for EBRT treatment planning (with the patient in fixation on flat couch in the treatment position):
Answer categories (several possible):
CT
MRI
PET-CT
CT is required
BT What imaging do you perform with the applicator in place?
Answer categories (one answer possible):
MRI for all applicator insertions
MRI for first applicator insertion and CT for subsequent insertions
CT for all insertions
Other (free text)
MRI with applicator in place for at least the first applicator insertion. 3D imaging (CT or MRI) must be done for all insertions.
Number of cervix cancer patients treated with combined intracavitary-interstitial technique (“Vienna applicator” or “Utrecht applicator” style) in the past 12 months (calendar year or year to date):
Application of needles in >20% of patients
94
Answer category:
Indicate number
EBRT What is your bladder filling strategy for external beam radiotherapy (planning and on treatment)?
Answer categories (one answer possible):
Intent of full bladder
Specific drinking protocol with specification of voiding and amount of fluid intake
Empty bladder
Drinking protocol with specification of voiding and amount of fluid intake
Number of cervix cancer patients treated with IMRT/VMAT in the past 12 months (calendar year or year to date)
Answer category:
Indicate number
Application of IMRT in 90% of patients
Overall experience with IMRT: Number of gynae/rectum/bladder patients treated with IMRT during the past 12 months (approximate number)
Answer category:
0-20
20-50
>50
How often is image guidance performed during external beam radiotherapy?
Answer categories (one answer possible):
Daily
Weekly
First 1-5 fractions
Other (free text)
Daily image guidance and bony registration
Which kind of image guidance is used during external beam radiotherapy?
Answer categories (several possible):
CBCT (kV CT)
kV orthogonal
Modalities suitable for bony registration, which can be CBCT, EPID, orthogonal kV, MVCT
95
EPID
MVCT
Other (free text)
How is patient set up performed?
Answer categories (one answer possible):
Skin marks
On line (daily) couch correction based on bony registration
Off line couch correction based on bony registration
Couch correction based on soft tissue registration
Other (free text)
Online daily couch correction according to bony fusion
Which CTV to PTV margin is used for the elective lymph node target (in mm):
Lateral:
Ant-post:
Cranio-caudal:
PTV margin ≤5mm
To which dose do you boost lymph nodes:
Answer categories (several answers possible):
For each option: a free text box will be available for comments e.g. for criteria for boosting.
no boost
50-55Gy
55-60Gy
>60Gy
Lymph node boosting is up to the institution and may be according to size of node. However, a certain prescription is recommended in the protocol.
Chemotherapy Which alternative chemotherapy schedules do you apply, in case concomitant chemotherapy cannot be delivered?
Answer categories:
Free text
Adjuvant chemotherapy: in which patients and with which schedule to you apply
96
adjuvant chemotherapy?
Answer categories:
Free text
Treatment planning systems
Which treatment planning system (vendor and version) are you using for EBRT
Answer categories:
Free text
Which treatment planning system (vendor and version) are you using for brachytherapy
Answer categories:
Free text
Substudies Are you interested in participating in translational research?
Answer categories (several answers possible):
Yes, by sending samples to other departments for analysis
Yes, by performing analyses in your own laboratory
No
Are you interested in participating in an EBRT substudy involving daily CBCT guided EBRT with delivery of plan of the day (library plans)?
Answer categories:
Yes
No
2432
97
22.4 APPENDIX 4. CLINICAL CASES FOR CONTOURING 2433
22.4.1 CASES FROM VIENNA, UTRECHT AND AARHUS, CONTOURING TABLES 2434
Will be provided later. 2435
2436
98
22.5 APPENDIX 5: EBRT CONTOURING ATLAS (COMPLEMENT TO CHAPTER 9) 2437
22.5.1 INTRODUCTION 2438
This appendix document describes the process for radiotherapy treatment planning of cervix cancer and has been developed for the 2439
purpose of the EMBRACE II study. A precise target volume definition is crucial for radiotherapy planning and IMRT treatments. It 2440
requires detailed knowledge of CT and MRI-based anatomy. In developing the EMBRACE II study, considerable time was spent 2441
discussing target definition and OARs. There are differences in views among radiation oncologists regarding their preferred volume of 2442
elective nodal irradiation, their PTV margins and organs at risk delineation. To ensure homogenous contours and to provide an efficient 2443
workflow when contouring, a step-by-step pictorial guide is provided for the delineation of tumor related target volume, nodal target 2444
volume and OARs. 2445
It is well recognized that there is overlap with chapter 9 on EBRT. However, this appendix part is meant as practical guide to contouring 2446
which may contain some redundancies. 2447
Please note that we have considered the target volume definition guidelines as used in the ICRU 50/62/83 and also the new concepts of 2448
ICRU 88 for brachytherapy. 2449
22.5.2 CLINICAL TARGET VOLUMES RELATED TO THE PRIMARY TUMOR 2450
The following abbreviations are used in the appendix: 2451
GTV: Gross Tumor Volume (at diagnosis). 2452
CTV: Clinical Target Volume = GTV + suspected microscopic tumor extension. 2453
ITV: Internal Target Volume = CTV + internal margins to compensate for internal motions. 2454
PTV: Planning Target Volume = CTV + set-up margin. 2455
Different imaging modalities are used for delineate of different volumes. To facilitate the comprehension of this stepwise contouring 2456
atlas, you can use the following schematic workflow (26.1 (App)) explaining which contours should be outlined on the MRI images and 2457
CT images respectively. 2458
Considering the difference in clinical practice of imaging in different centers, we propose two different ways of contouring. The choice 2459
of the strategies is at the discretion of the center/treating doctor. Each of these approaches needs at least a diagnostic MRI to contour 2460
the primary targets (GTV-Tinitial and CTV-Tinitial HR). 2461
As explained in the protocol, the planning CT should be done according to a bladder filling protocol allowing the patient to have a 2462
comfortably full bladder. In addition to their diagnostic MRI, some patients benefit from high quality MRI images in treatment position 2463
in which the range of motion of the cervix and uterus with different fillings of the bladder/bowel can be observed and expectations of 2464
most likely motion scenarios during radiotherapy can be defined and in which the image registration between the planning CT and the 2465
MRI is reliable. For these cases, we recommend an individualized approach in which the CTV-T LR initial margin is adapted according to 2466
the different image sets. As an example: in case of a completely empty rectum at time of treatment planning, it is more likely that the 2467
CTV-T LR initial will move in anterior direction and the ITV margin may be increased in anterior direction and reduced in posterior 2468
direction (see figure 26.1 (App)). 2469
99
2470
Figure 22.5.1 (App) Schematic workflow for contouring primary target and nodal target and OARs on diagnostic MRI, MRI in treatment 2471
position and CT 2472
2473
22.5.3 FIXED MARGIN APPROACH 2474
STEP 1 2475
Considering that every patient has a diagnostic MRI, contour the following structures on the MRI images: 2476
The GTV-Tinitial (contour in red) is the extension of the cervical tumor defined by T2 weighted MRI supported by clinical investigation 2477
and PET-CT (figure 22.5.2). 2478
2479
Figure 22.5.2 GTV-Tinitial on MRI (T2), A : axial view, B : sagittal view 2480
2481
A B
100
STEP 2 2482
Outline the CTV-T HRinitial (contour in magenta). It’s the initial high risk CTV-Tinitial including GTV-Tinitial and any remaining cervix not 2483 infiltrated by the tumor (figure 3). 2484
2485
Figure 25.5.3 CTV-T HRinitial (magenta) and GTV-T initial(red) on MRI (T2), A : axial view, sagittal view 2486
STEP 3 2487
Do the registration (fusion) of the MRI images with the planning CT images. The planning CT should have been done according to the 2488
bladder filling protocol (see section 9.2). Transfer all previous MRI contours (GTV and CTV’s) to the planning CT. If it is impossible to 2489
appropriately register the bony structures on the planning CT with the ones on MRI (due to positioning differences for example), try to 2490
match locally (the cervix region) on the soft tissue. Once fused, verify your MR-based contour on the planning CT. 2491
On the MRI, identify the CTV-T LRinitial (contour in dark green) which includes: 2492
Initial CTV-T HR initial 2493
the complete parametria bilaterally 2494
the whole uterus 2495
uninvolved vagina with a 20 mm margin measured from the most inferior position of the HR CTV-Tinitial, along the vaginal axis 2496
(not starting in the fornix) 2497
CTV-T HR plus a margin of about 5 mm anterior and posterior towards bladder and rectum (excluding the non-involved walls) 2498
In case of involvement of the pelvic wall, sacro-uterine ligaments, meso-rectum or other involved structures (e.g. bladder, 2499
rectum) a 20 mm margin around the initial HR CTV-Tinitial will be extended into these structures as appropriate 2500
In case of excessive uterine/ligamentum latum infiltration consider to include ovaries into CTV-T LRinitial 2501
2502
The CTV-T LRinitial volume is normally delineated as a single contiguous volume but for the purpose of these instructions we have 2503
separated the structures to aid description. The MRI information will help you to contour these volumes on the planning CT. 2504
Extend the outline of the CTV-T HRinitial to include the whole uterus and 20 mm in the vaginal direction. Subsequently, outline both 2505
parametria and paravaginal tissue (figure 22.5.4A and 22.5.4B) even if not involved with disease, the borders of the parametria are 2506
outlined in the figure 22.5.5 and defined on the table 22.5.1. 2507
In the case of vaginal extension, the CTV-T LRinitial lower limit is 2 cm below the caudal extension of the initial HR CTV-T initial. If the whole 2508
vagina had to be outlined, the CTV-T LRinitial should include the vaginal introitus which is located below the level of the pelvic floor (e.g. 2509
PIBS minus 2 cm). 2510
101
STEP 4 2511
Generate the ITV-T LR by adding a 10mm margin around the CTV-T LRinitial cranio-caudally and antero-posteriorly and 5 mm laterally 2512
(figure 22.5.4C, figure 22.5.4D). 2513
On the ITV-T LR, erase the most caudal contours so that the most caudal delineation of the ITV-T LR correspond to the most caudal 2514
outline of the CTV-T LRinitial (figure 22.5.4E and 22.5.4F). 2515
2516
Figure 22.5.4 ITV-T 45 (light green), CTV-T LR (dark green), CTV-T HR initial (magenta), GTV-T initial (red), MRI (T2) A, C, F : axial view, B, 2517
D, F : sagittal view 2518
2519
102
2520
Location Anatomic structures
Anteriorly Posterior wall of bladder or posterior border of external iliac
vessel
Posteriorly Uterosacral ligaments and mesorectal fascia
(figure 6)
Laterally Medial edge of internal iliac and obturator vessels
Superiorly Top of fallopian tube/ broad ligament/uterine arteries.
Depending on degree of uterus flexion, this may also form
the anterior boundary of parametrial tissue.
Inferiorly Urogenital diaphragm
Table 22.5.1 Definitions for Parametria delineation 2521
2522
Figure 22.5.5 MRI (T2) A : Coronal, B : Axial, ; a :Superior limit (uterine arteries), b : lateral limit (medial edge iliac vessels region) , 2523
c :posterior limit (mesorectum) 2524
103
2525
Figure 22.5.6 MRI (T2) axial, initial CTV-T LRinitial (dark green) Borders of the parametria 2526
2527
22.5.4 INDIVIDUALIZED APPROACH 2528
Follow the step 1, step 2 as explained above. 2529
STEP 3 2530
On the MRI, identify the CTV-T LRinitial (contour in dark green) as defined for the standard approach. 2531
The CTV-T LRinitial volume is normally delineated as a single contiguous volume but for the purpose of these instructions we have 2532
separated the structures to aid description. The CTV-T LR is outlined on the MRI images. 2533
Extend the outline of the CTV-T HRinitial to include the whole uterus and 20 mm in the vaginal direction. Subsequently, outline 2534
both parametria (figure 3A and 3B) even if not involved with disease, the borders of the parametria are outlined in the figure 2535
25.5.5 and defined on the table 25.5.1. 2536
In the case of vaginal extension, the CTV-T LRinitial lower limit is 2cm below the caudal extension of the tumor. If the whole 2537
vagina had to be outlined, the CTV-T LRinitial should include the level of the introitus located below the level of the pelvic floor. 2538
2539
STEP 4 2540
Do the registration (fusion) of the MRI images with the planning CT images. The planning CT should have been done according to the 2541
bladder filling protocol (see section 9.1). Transfer all previous MRI contours (GTV and CTV’s) to the planning CT. If it is impossible to 2542
appropriately register the bony structures on the planning CT with the ones on MRI (due to positioning differences for example), try to 2543
match locally (the cervix region) on the soft tissue. Once fused, verify your MR-based contour on the planning CT. 2544
On the planning CT, generate the ITV-T LR by adding an individualized margin around the CTV-T LR initial for the different directions 2545
(figure 25.5.7A and 25.5.7.B). The margins are independent in any direction and are chosen according to the information on the 2546
bladder, rectum, uterus, and primary target motion from the different image set available (example figure 25.5.8). 2547
2548
104
2549
Figure 7 MRI (T2) axial, ITV-T 45 (light green), CTV-T LR initial (dark green), CTV-T HR initial (magenta), GTV-T initial (red), A,C: axial view, 2550
B,D: sagittal view 2551
2552
On the ITV-T LR, erase the most caudal contours so that the most caudal delineation of the ITV-T LR corresponds to the most caudal 2553
outline of the CTV-T LR initial (figure 25.5.7C and 25.5.7D). 2554
105
2555
Figure 25.5.8 Margins for the ITV-T LR if using a diagnostic MRI for the fusion (left) or an MRI in treatment position (right) 2556
22.5.5 CLINICAL TARGET VOLUMES FOR NODAL METASTASES AND NODAL REGIONS 2557
*we recommend that the step 1 and step 2 are done on the MRI but they could be done on the CT as well. 2558
STEP 5 2559
Outline the GTV-N (contour in red) if the nodes are visible on the MRI for each pathological lymph node (figure 9B). They must be 2560
contoured and numbered, even if nodal boosting is not contemplated. PET-CT should primarily be used for overall guidance and not for 2561
precise delineation of the pathological nodes. Include extracapsular extension if visible. In case of nodes beyond the extension of pelvic 2562
MRI individual contours should be based on PET-CT appearance. Nodes are considered pathologic if they are: 2563
FDG PET positive 2564
Short axis diameter of ≥ 10 mm on CT or MRI 2565
Diameter of 5-10 mm on MRI with pathological morphology: irregular border, high signal intensity and/or round shape. 2566
STEP 6 2567
On the MRI/CT contour the CTV-N (contour in turquoise) for each pathologic lymph node with 0-3 mm margin around each GTV-N 2568
taking possible progression during treatment planning interval and not visible extra-capsular extension into account, avoiding bones 2569
and muscles. Furthermore, partial volume effect may lead to different appearance of the upper and lower boundary on CT and MRI. 2570
The total CTV-N should ideally encompass the maximum extension of the pathologic node as visualized on both CT and MRI. For 2571
pragmatic purpose and because there is only minor movement in nodal region, there is no need to draw a real ITV-N. The volume will 2572
allow for adequate inclusion into CTV-E and together with the PTV-N margin also if boosting is intended. Numbering of individual CTV-N 2573
should be consistent with GTV-N. 2574
106
2575
Figure 25.5.9 A : CT scan, axial view B : MRI (T2) axial view, CTV-N1 (turquoise), GTV-N1 (red), 2576
2577
The CTV-E (contour in blue) encompasses all individual CTV-N and the bilateral lymph node regions for elective nodal irradiation. 2578
Risk patients Lymphatic nodal region to contour
Low risk Internal iliac, external iliac, obturator and presacral regions
Intermediate risk common iliac, internal iliac, external iliac, obturator, and presacral regions, (groins
in case of distal vaginal infiltration)
High risk para-aortic, common iliac, internal iliac, external iliac, obturator, and presacral
regions, (groins in case of distal vaginal infiltration)
The extent of the nodal regions within CTV-E is determined according to the risk spread as defined in the introduction of chapter 9: 2579
STEP 7 2580
Transfer all previous MRI contours (GTV-N and CTV-N) to the planning CT if applicable 2581
Identify the iliac blood vessels (figure 22.5.11A). The most superior axial outline should be at the aortic bifurcation. The most 2582
inferior border should be at the level of ischial spine and upper edge of obturator foramen were internal iliac vessels leave or 2583
enter the true pelvis ) which represents the caudal margin of the external and internal iliac vessels. 2584
Nodal regions should be contoured on the planning CT or pelvic MRI including the relevant vessels with at least 7 mm of 2585
perivascular tissue including pertinent clips or lymphocysts (figure 22.5.11B) (in case of prior nodal resection or 2586
lymphadenectomy). See the table 4 at the end of this annex for a more detail lymph nodes anatomical boundaries definition. 2587
Using the drawing tools, join the outlines around the internal and external iliac vessels parallel/medial to the pelvic sidewall 2588
(figure 22.5.11C). This ensures the obturators and infra-iliac nodes to be included. Internal iliac border should be extend to the 2589
pelvic sidewall. 2590
Continue to contour inferiorly to cover the obturator nodes (figure 22.5.10). The most inferior axial slice to include should be 2591
at the level of the pelvic floor (usually below the femoral heads). This outline should not include muscle or bone. 2592
107
2593
Figure 22.5.10 Contouring obturator nodal region on a CT scan, CTV-E (blue) 2594
2595
2596
Figure 25.5.11 Contouring steps for internal and external nodal region on a CT scan, A contour of illiac vessels, B :extension of vessel 2597
volume, C : CTV-E (blue) 2598
108
To cover the presacral region, connect the volumes on each side of the pelvis (figure 22.5.12A) with a 10-mm strip over the 2599
anterior sacrum (figure 22.512B) to the lower level of S2. You do not need to extend into the sacral foramina (figure 22.5.13) 2600
For the common iliac vessels, extend the outline posterolaterally, it must be extended to the psoas muscle and vertebral body. 2601
2602
2603
2604
2605
Figure 25.5.12 Contouring steps for sacral nodal region on a CT scan, B : CTV-E (internal, external and presacral nodal region (blue) 2606
2607
Figure 25.5.13 Contouring sacral nodal region on a CT scan , arrows : sacral foramina 2608
2609
109
The level of the cranial pelvic irradiation field border is defined according to the patients risk. 2610
Risk patients Cranial border of irradiation field
Low risk One slice below the bifurcation of common iliac artery
Intermediate One slice below the aortic bifurcation
High risk Cranial border of L1 with a minimum of 3 cm superior to the upper border of the
last positive lymph node(s)
Table 22.5.3 Superior irradiation field border 2611
2612
22.5.6 PARA-AORTIC NODES 2613
STEP 8 2614
Nodal regions should be contoured on the planning CT including the relevant vessels (vena cava and aorta) (figure 22.5.14A) with at 2615
least 7 mm of perivascular tissue including pertinent clips or lymphocysts (figure 22.5.14B) 2616
STEP 9 2617
Edit to exclude any muscle or bone. Subsequently, extend the contour posterior-laterally along the vertebral body (figure 22.5.14C) to 2618
cover the left para-aortic area or any lymphocysts. 2619
2620
Figure 22.5.14 Contouring paraaortic region on a CT scan, axial view, A : Great vessels, B : 7mm extension, C : CTV-E (blue) 2621
22.5.7 INGUINAL NODES 2622
Inguinal lymph nodes irradiation should be added in case of positive inguinal lymph node or involvement of the lower third of the 2623
vagina. 2624
STEP 10 2625
The inguinal/femoral region should be contoured as a compartment with any identified nodes included (especially in the lateral inguinal 2626
region). The outline should have a minimum of 7-10 mm margin around vessels. The caudal extent of the inguinal region should be 2 2627
110
cm caudal to the saphenous/femoral junction. The posterior border is the ventral fascia of the pectineus muscle. The lateral border is 2628
the ventral fascia of the ileopsoas and sartorius muscles (figure 22.5.15). 2629
2630 2631
2632
Figure 22.5.15 Left inguinal lymphatic region, CT, a : sartorius, b : pectineus muscle, c : adductor longus, CTV-E (blue) 2633
2634
22.5.8 PLANNING TARGET VOLUMES (PTV) 2635
STEP11 2636
Create one large volume (ITV 45) by fusing the following contours: ITV-T LR, and CTV-E. 2637
STEP12 2638
Add a margin of 5mm to the ITV 45 to create the PTV 45. 2639
Lymphocysts after lymphatic surgery should be included into PTV 45, In case lymphocysts shrink extensively during ERBT, re-contouring 2640
and re-planning should be considered (figure 22.5.16). 2641
2642
111
2643
Figure 25.5.16 CT,PTV 45 (purple), ITV-T 45 (orange), CTV-E (blue), CTV-T LRinitial (light green) ; A, B, C, D, E : axial view, F : sagittal view 2644
22.5.9 NODAL BOOST 2645
STEP13 2646
Add a 5mm margin to each CTV-N1, CTV-N2, … to create PTV-N1, PTV-N2, … 2647
2648
112
22.5.10 PRIMARY TARGET CONTOURING SUMMARY WITH DIAGNOSTIC MRI* 2649
On MRI 1- Contour the GTV-Tinitial. It’s the extension of the primary tumor at the cervix
2- Outline the CTV-T HRinitial. It’s the initial high risk CTV-T including GTV-Tinitial and any remaining cervix not infiltrated by the tumor
Surimposition/Registration/ fusion between the MRI and the planning CT*
* if impossible to fuse the MRI with the planning CT on the bony structure, try to match locally (the cervix region) on the soft
tissue or surimpose the images side by side. Once fused, verify your MR-based contour on the planning CT and do adjustments if
necessary
On CT 3- Contour the CTV-T LRinitial in including the following structures: -the CTV-T HRinitial -a 20 mm margin centripetal around GTV-Tinitial in the direction of the vagina -the complete parametria bilaterally -the whole uterus -the sacro-uterine ligaments and the mesorectum if involved -In case of excessive uterine/ligamentum latum infiltration consider to include ovaries into CTV-T LRinitial -invaded organs (bladder, rectum, sigmoid, bowel)
4- Contour GTV-N and CTV-N (margin 0-3mm) and numerate them accordingly 5- Delineate the CTV- E in contouring the nodal region corresponding to the patient risk category and including all the CTV-N 6- Generate the ITV-T LR by adding a 10mm margin (fixed margin approach) around the CTV-T LRinitial cranio-caudally and antero-posteriorly and 5mm laterally
7- On the ITV-T LR, erase the most caudal contours so that the most caudal delineation of the ITV-T LR correspond to the most caudal outline of the CTV-T LRinitial
8- Join the ITV-T LR and the CTV-E outline to form the ITV 45.
9- Generate the PTV 45 in adding a 5mm margin to the ITV 45
10- Outline the OAR
2650
2651
113
22.5.11 PRIMARY TARGET CONTOURING SUMMARY WITH AN MRI IN TREATING POSITION 2652
2653
On MRI 1- Contour the GTV-Tinitial. It’s the extension of the primary tumor at the cervix
2- Outline the CTV-T HRinitial. It’s the initial high risk CTV-T including GTV-Tinitial and any remaining cervix not infiltrated by the tumor
3- Contour the CTV-T LRinitial in including the following structures:
-the CTV-T HRinitial -a 20 mm margin centripetal around GTV-Tinitial in the direction of the vagina -the complete parametria bilaterally -the whole uterus -the sacro-uterine ligaments and the mesorectum if involved -In case of excessive uterine/ligamentum latum infiltration consider to include ovaries into CTV-T LR initial -invaded organs (bladder, rectum, sigmoid, bowel
Surimposition/Registration/ fusion between the MRI and the planning CT*
On MRI and or CT 4- Contour GTV-N and CTV-N (margin 0-3mm) and numerate them accordingly
5- Delineate the CTV- E in contouring the nodal region corresponding to the patient risk category and including all the CTV-N 6- Outline the OAR
On CT 7- Generate the ITV-T LR by adding an individualized margin (individualized margin approach) around the CTV-T LR independently in each direction
8- On the ITV-T LR, erase the most caudal contours so that the most caudal delineation of the ITV-T LR correspond to the most caudal outline of the CTV-T LRinitial
9- Join the ITV-T LR and the CTV-E outline to form the ITV 45
10- Generate the PTV 45 in adding a 5mm margin to the ITV 45
2654
114
2655
2656
2657
Figure 22.5.1 Atlas example FIGO IB2 cervical cancer with pathological lymph nodes. MRI (T2) in treatment position, axial slices at 2658
regular interspaces from left to right and top to bottom, CTV-E (magenta), GTV-N (orange), CTV-T LR (green). 2659
2660
115
2661
2662
2663
Figure 22.5.2 Continued: MRI (T2) in treatment position, axial slices at regular interspaces from left to right and top to bottom, CTV-E 2664
(magenta), GTV-N (orange), CTV-T LR (green), GTV-T initial (yellow), CTV-T HR initial (light blue). 2665
2666
116
2667
2668
2669
Figure 22.5.3 Continued: MRI (T2) in treatment position; top left axial and top right sagittal CTV-E (magenta), CTV-T LR (green), GTV-T 2670
initial (yellow), CTV-T HR initial (light blue); middle left axial and middle right sagittal CTV-E (magenta), CTV-T LR (green), GTV-T initial 2671
(yellow), ITV-T LR using standard margins (orange) and PTV45 (red); bottom left axial bottom right sagittal CTV-E (magenta), CTV-T LR in 2672
treatment position (green) and three additional positions from different fused MRI and PET-CT scans (light blue), GTV-T initial (yellow), 2673
ITV-T LR using individual margins (orange) and PTV45 (red). 2674
2675
117
22.5.12 CONTOURING OF ORGANS AT RISK 2676
The outer contour of the following organs should be delineated separately: 2677
Bladder: Outline the whole organ including the bladder wall and the bladder neck (figure 17). 2678
2679
Figure 22.5.17 CT, Bladder contour (yellow) A :axial view, B : Sagital view, C : Coronal view 2680
Femoral heads: Both femoral head and neck to the level of the trochanter minor. (figure 22.5.18) 2681
Rectum: Outline the rectum from the ano-rectal sphincter (level of PIPS) to the recto-sigmoid junction (retroperitoneal deflection), 2682
including the rectal wall (figure 22.5.19). 2683
2684
Figure 22.5.18 Right femoral head contour (orange), A : axial view, B : coronal view 2685
118
Sigmoid: From the recto-sigmoid junction to the left iliac fossa (figure 22.5.18). 2686
2687
Figure 22.5.19 CT, rectum contour (brown) and sigmoid contour (orange), A :axial view, B : Sagital view, C : Coronal view, D : 3-D 2688 reconstitution 2689
2690
119
Bowel: Outer contour of bowel loops including the mesenterium. Do not include abdominal cavity without bowel or sigmoid (figure 2691
22.5.20). 2692
2693
Figure 22.5.20 CT. bowel contour (green) 2694
2695
22.5.13 FOR PARA-AORTIC IRRADIATION IN ADDITION 2696
2697
Kidneys: outer contour excluding pyelum (figure 22.5.21) 2698
Figure 22.5.21 Kidney contouring 2699
120
Spinal cord: outer contour of spinal cord, contour down to L2 (figure 22.5.22) 2700
2701
Figure 22.5.22 CT. Spinal cord 2702
2703
Lymph node
regions to
encompass
Anatomical boundaries
( adapt where necessary to include all visible lymph nodes)
Cranial Caudal Anterior Posterior Lateral Medial
Para-aortic
nodes
Cranial border of
L1 with a
minimum of 3
cm superior to
the upper
border of the
last positive
lymph node(s)
One slice below
aortic
bifurcation
7 mm margin
around vessels
excluding bowel
loops or other
organs
ventro-
lateral contours
of vertebral
bodies until
connection with
psoas muscle
along outer
contour of psoas
muscle with a
minimum of 7
mm around
vessels
excluding bowel
loops or other
organs
121
Common iliac
nodes
One slice below
aortic
bifurcation
One slice
below bifurcatio
n of common
iliac artery
7 mm margin
around vessels
excluding bowel
loops
Ventro-lateral
contours of
vertebral bodies
until connection
with
psoas/iliopsoas
muscles
excluding nerves
along outer
contour of psoas
muscle , up to 7
mm around
vessels
excluding
muscle
7 mm margin
around vessels
excluding bowel
loops
Pelvic nodes
including
Internal iliac
nodes
External iliac
nodes
Obturator
nodes
One slice
below bifurcatio
n o common
iliac artery
Pelvic floor
(usually at the
upper part of
the obturator
foramen, below
the femoral
head, where
internal iliac
vessels leave or
enter the true
pelvis)
7-17 mm ventral
to external iliac
vessels not
extending into
the abdominal
wall
ventro-medial
fascia of
piriformis
muscle/sacrospi
nous ligament
ventro-medial
fascia of
iliopsoas muscle,
bony pelvic
sidewall and
obturator
internus muscle
7 mm around
vessels
excluding bowel
loops, bladder
wall, lateral
border of
parametrium
and mesorectal
fascia
Presacral
nodes
upper border S1 lower border S2 1 cm in front of
S1/2
ventral border
S1/2
medial borders
of pelvic node
compartments
Inguinal
nodes
Midfemoral
head, external
iliac vessels
leave bony
pelvis as femoral
vessels
Lower edge
trochanter
minor, about 2
cm below
junction vena
femoralis/ vena
saphena manga
7-10 mm margin
around vessels
ventral fascia of
pectineus
muscle
medial fascias of
ileopsoas
/sartorius
muscles
7 mm margin
around vessels
excluding,
peritoneal
fascia, lateral
fascia of rectus
abdominis
muscle, latero-
ventral fascias
pectineus/adduc
tor
longus/brevis
muscles
Table 22.5.4 : Lymph nodes regions borders 2704
2705
122
22.6 APPENDIX 6: MEASUREMENT AND REPORTING OF SUV 2706
Measurement and reporting of SUV in primary tumour and lymph nodes is not mandatory in EMBRACE II, but when reported to the 2707
database, the following procedure should be used: 2708
In general the FDG PET/CT: EANM procedure guidelines for tumour imaging: version 2.0 should be followed (Boellaard R. et al. 2709
2015). 2710
CT can be performed as either a low-dose CT-scan for attenuation correction and anatomical correlation or as a diagnostic CT-2711
scan. 2712
Scans should be performed according to local guidelines with regard to fast and blood glucose levels. 2713
Image reconstruction should be performed according to local guidelines. 2714
Imaging should be evaluated using software that can display fused CT and PET data and use a SUV scale. 2715
Time from injection to scan start should be between 60-90 minutes. 2716
Reported to the database: 2717
o SUVmax of the primary tumour 2718
o SUVmax for each lymph node 2719
o Necrosis (yes/no) for each lymph node 2720
2721
22.7 APPENDIX 8: CRFS (CH 16) 2722
This Appendix refers to a large excel file which is in principle based upon the CRF design of EMBRACE I with altogether 8 forms: 2723
1. Registration Form 2724
2. Status at Diagnosis Form 2725
3. Baseline Morbidity Form 2726
4. Status at Brachytherapy Form 2727
5. Treatment and DVH Form 2728
6. Follow-up Form 2729
7. Off Study and Vital Status Form 2730
8. Curative Salvage Treatment Form 2731
The CRFs have been systematically reworked during the last 6 months for most of the 8 parts and still need to be finalized with about 2732
80% already finished (estimate). 2733
This rework has been done based on our experience with EMBRACE I and the design of the CRFs and the evaluation of parameters. In 2734
addition the design of EMBRACE II was taken into account reflecting the major (new) endpoints. As EBRT has become an additional 2735
issue of major importance in EMBRACE II, this is reflected in the respective forms. The rework has tried to follow the EMBRACE I 2736
parametrization in order to provide the basis for comparison of data between EMBRACE I (RetroEMBRACE) and EMBRACE II. 2737
2738
22.8 APPENDIX 9: PRINCIPALS AND STRUCTURES OF EMBRACE RESEARCH GROUP 2739
Research work is organised based on written project proposals with a short and a long protocol version. 2740
Research protocols are organised according to classical research proposal structure for grant applications 2741
Research protocols have to result in minimum one major publication in a peer reviewed journal 2742
123
Research funding is not available directly through the EMBRACE study 2743
Research is organised within working groups focussing on a specific topic with a coordinator and co-workers 2744
Milestones to be defined with time lines in a research proposal: who, what, when 2745
Updates to be given in person on the occasion of meetings: Gyn GEC ESTRO network, midyear, annual EMBRACE end of the year 2746
Responsibility for project plan and research performance: Working group coordinator. Working group coordinator is assigned for 2 2747
years, can be renewed 2748
Bilateral Agreement on this outline with main mentor/mentor group before application 2749
Overall Agreement on all project outlines by EMBRACE Research mentor group continuously: start after 1st application round 2750
Publication authorship (for first major publication): Working group coordinator is first author, main mentor is senior author. In case of 2 2751
persons, co-equal authorship foreseen authors are persons with active participation in the publication project one authorship goes to 2752
one of the EMBRACE coordinators (co-mentor) provisional title of first major publication and authorship should be part of the short and 2753
long proposal version, may be adapted later 2754
EMBRACE Research Leader group are the Study coordinators plus senior advisors 2755
EMBRACE Research Mentor group: Richard Pötter, Kari Tanderup (coordinators) 2756
EMBRACE Research WG Coordinator group: all workgroup coordinators, 2757
Milestones and timelines for project progress and publication process have to be kept carefully in order to make this complex research 2758
structure feasible and to ensure our data to be handled in appropriate way . 2759
In case of somebody going repeatedly and significantly beyond timelines not fulfilling milestones in regard to project and publication 2760
process without upfront providing a rationale to the EMBRACE research leader group, the function of the coordinator and the 2761
authorship role will be re-considered and decided by the cooperative research leader group. 2762
Overall organisation structure: Research leader group regular 6 monthly telephone conferences. A work group coordinator or mentor 2763
may be invited, if appropriate organised by Vienna or Aarhus (RP, KT) decisions are taken by majority 2764
The overall EMBRACE Research group, working group coordinators together with mentors and co-workers meets on the occasion of 2765
annual EMBRACE meetings and Gyn GEC ESTRO network meetings, if feasible. 2766
Each working group and mentor group works according to its own specific working plan. Minimum actions to be taken by the working 2767
groups are telephone conference meetings in 3 months intervals (with the main mentor available) with a pre-meeting agenda and 2768
summarizing minutes (results). This is to be communicated in cc to the coordinators RP, KT. 2769
No extra funding is at present available for the performance of the research work. Specific funds are therefore encouraged to be 2770
applied for at the regional/national/ European/international level as appropriate after discussion and agreement on the proposal with 2771
the EMBRACE RESEARCH leader group. 2772
2773
2774
124
22.9 APPENDIX 10: PATIENT INFORMATION 2775
Patient information needs to be adapted to the needs, legislative and ethical requirements of each country and radiotherapy 2776
department. To facilitate this process and to maintain some uniformity, parts of the following paragraphs could be included in the 2777
written patient information but this information should be adjusted according to local institutional standard treatment policies and are 2778
subject to local ethical committee approval. In addition, a study specific consent form will need to accompany the patient information 2779
form that needs to be adapted to fulfill the regulations of the local ethical committee. 2780
Summary 2781
You have been asked to participate in a study for patients with cervical cancer who will be treated with a combination of external beam 2782
radiotherapy, chemotherapy and brachytherapy (internal radiation). 2783
The aim of this study is to collect exact details about: 2784
Radiation dose to the tumor and surrounding normal organs 2785
Effect of therapy on tumor control 2786
Side effects of treatment 2787
Quality of life during and after treatment 2788
This is a study in which only details about the treatment and its effects will be registered. You will receive the same treatment if you do 2789
not participate in this study. The study is planned to include more than 1000 patients from approximately 25 different international 2790
radiotherapy departments. The radiotherapy departments who collaborate in this study all use advanced level technological methods 2791
to deliver radiation image guided, as precisely and optimally as possible, to the tumor while sparing the surrounding healthy organs. In 2792
this document you can read more information about the treatment, the possible side effects of treatment and this study. 2793
Background 2794
The combination of external beam radiotherapy, chemotherapy and brachytherapy is the current standard treatment for patients with 2795
locally advanced cervical cancer. The treatment starts with external beam radiotherapy together with chemotherapy. Brachytherapy 2796
(internal radiation) will be started during the last part of external beam treatment or starts when external beam treatment has ended. 2797
In the first EMBRACE study that was completed in 2015 more than 1000 patients participated. This study focused on implementing a 2798
brachytherapy treatment method in which the radiation dose was shaped to the individual patients anatomy or position of the tumor 2799
and the healthy normal surrounding organs using MRI imaging at time of brachytherapy. Results of this and other studies indicate that 2800
in patients with small tumors high doses of radiation can safely been given resulting in a very high chance that the cancer will be cured. 2801
For these patients brachytherapy dose to normal surrounding organs can be lowered while maintaining the high chance of tumor 2802
control. On the other hand, in patients with larger tumors a higher dose of brachytherapy could be safely given with advanced 2803
brachytherapy techniques and this higher dose resulted in an improved chance of tumor control. 2804
The current EMBRACE-II study will collect and register details from patients who have been treated with advanced brachytherapy 2805
techniques including MRI at time of brachytherapy, and with advanced external beam radiotherapy image guided techniques. Based on 2806
the results described above in EMBRACE-II: 2807
External beam radiotherapy will be done using intensity modulated radiotherapy, a technique that results in less radiation 2808
dose to surrounding healthy organs (bowel, bladder). Furthermore, each day patients will be positioned as accurate as possible 2809
on the treatment machine using imaging on the machine. This will increase the precision of treatment. 2810
For brachytherapy it will be routinely possible to adjust the devices used to deliver internal radiation to the individual anatomy 2811
and position of the tumor and surrounding healthy organs. Together with MRI imaging at time of brachytherapy, this will 2812
increase the precision of treatment. For smaller tumors this will result in less dose to healthy surrounding organs, while for 2813
larger tumors this will allow to increase the radiation dose necessary to effectively treat the tumor. 2814
125
External beam radiotherapy 2815
External beam radiotherapy is an outpatient treatment that takes approximately 20-30 minutes per day and is usually given each day (5 2816
days a week). In total 25 external beam radiotherapy treatments are given over a period of 5-6 weeks. 2817
Side effects of external beam irradiation 2818
During the 5-6 week period that external beam radiotherapy is given, side effects will gradually develop, usually starting after 2-3 2819
weeks. The side effects are most pronounced during the last 2 weeks of external beam radiotherapy and the first 2 weeks after 2820
completion. During this period the tumor will decrease in size and sometimes patients will notice a change in discharge form the vagina. 2821
Side effects during and shortly after treatment include: 2822
Irritation of bowel resulting in softening of stools or diarrhea, sometimes with bowel cramps and seldom with a little blood in 2823
the stool. This results in having to go to the toilet more often for bowel movements. 2824
Irritation of the bladder, which leads to increased urgency or need to go to the toilet more often to pass urine, sometimes with 2825
a burning sensation. 2826
Irritation of the vagina. 2827
Loss of energy or feeling tired. 2828
Brachytherapy 2829
With brachytherapy radiation is given inside the tumor using an applicator. The placement of the applicator is done using a form of 2830
anesthetic (general or spinal). The applicator uses hollow tubes that are placed in the vagina and through the cervix into the cavity of 2831
the uterus (womb). It may be necessary to place additional hollow tubes or needles directly in the tumor area. Using an MRI scan with 2832
the brachytherapy applicator in position the radiation dose can be optimally shaped. During the treatment a radioactive source will be 2833
placed in the hollow tubes in the area of the tumor for some time to deliver the radiotherapy dose. How long the treatment takes and 2834
how much treatments are given depends on the equipment used and your radiation oncologist will provide more detailed information 2835
on this procedure. 2836
Side effects of brachytherapy 2837
In period when brachytherapy is given there usually are already side effects from external beam radiotherapy. In addition to these, 2838
there may be some bleeding from the vagina, which should stop within two days after treatment. There may be some additional 2839
soreness of the vagina or with passing urine after the procedure. 2840
Chemotherapy 2841
Chemotherapy will be given using the drug cisplatin that will be given on one day each week during the first five weeks of external 2842
beam radiotherapy. Cisplatin is given intravenously, in the bloodstream. 2843
Side effects of chemotherapy 2844
Most common side effects of this weekly cisplatin treatment include: 2845
Feeling sick (nausea) or having to vomit. To prevent this the treatment will be combined with medication to prevent this. 2846
Cisplatin can damage the kidney. For this reason additional fluid will be given together with the drug intravenously. The 2847
function of the kidney will be tested each time before the treatment is given. 2848
The chemotherapy temporary affects the normal blood cells. The number of blood cells will be tested each time before the 2849
treatment is given. A drop in white blood cells can result in an increased risk of infections. A drop in red blood cells can result 2850
in tiredness and shortness of breath. A drop in blood platelets can result in bruising or bleeding more easily. 2851
Seldom side effects include loss of taste, loss of appetite, some hearing loss, tingling or numbness in toes or fingers. 2852
126
Long term side effects of treatment 2853
Side effects that arise during or shortly after treatment usually pass away two weeks after treatment. However in the long run 2854
radiotherapy can directly damage some of the normal organ function or cause tissue to become less elastic (fibrosis). This can cause 2855
side effects that may become more apparent during the years following treatment. Your radiation oncologist will provide you with 2856
information on whom to contact in case of symptoms. These side effects may include: 2857
Ovaries will stop functioning. This causes infertility and causes early menopause in women that have not had their menopause. 2858
The vagina can become less elastic, narrower and dryer. Altogether these side effects may affect your sex life. The use of 2859
vaginal lubrication and vaginal dilators, to stretch the vagina, is recommended and you can receive more information on this 2860
subject separately. 2861
Parts of the bowel in the pelvic area may become less elastic and function less well. This can result in more frequent, loose 2862
stools and bowel cramps. Seldom this results in constipation or a bloated feeling. 2863
Due to reduced elasticity of the bladder it can not stretch as much which can give the sensation that its is full sooner. 2864
Swelling of the legs may be a result of fibrosis along the draining lymphatic tissue in the pelvis. 2865
Occasionally increased growth of small blood vessels in the mucosa of the bowel, bladder or vagina may cause bleeding. 2866
After treatment 2867
After treatment you will have regular outpatient visits with your radiation oncologist. These visits are used to check on the effect of 2868
treatment to control the tumor but also possible side effects. In the first year they will be every 3 months, during the second and third 2869
year every 6 moths and then yearly up to five years after treatment. During these visits a gynecological examination will be done. In 2870
addition, both at 3 months and one year after treatment a MRI scan will be made. 2871
Quality of life investigation 2872
Quality of life investigation is done using a questionnaire. The questionnaire is handed out before treatment starts, during treatment 2873
and at regular intervals up to 5 years after treatment. The questionnaire consists of 54 questions and will take approximately 20-30 2874
minutes to fill in. These questions ask you about the most common symptoms (side effects) of treatment, but also ask about more 2875
general functioning such as physical activity and emotional functioning. Using these questionnaires you can provide direct information 2876
on what the consequences of treatment are for your wellbeing. The information from these questionnaires provides important results 2877
for the study. Strict privacy is enforced and the information from the questionnaires will be handled under coded. 2878
Study participation 2879
The treatment with expected outcome and side effects as described above is the standard treatment. You will receive the same 2880
treatment if you do not participate in this study. The aim of this study is collect and register details about the treatment, the outcomes 2881
of treatment, side effects and quality of life. You will have to decide if you will participate in this study or not. If you decide to 2882
participate you will be asked to sign the written informed consent form. It is always possible to withdraw your study participation at any 2883
point in time. Your radiation oncologist may also propose to withdraw from the study if that may benefit your situation. If you decide 2884
not to participate you will receive the same standard treatment and this will not in any way affect the relationship with your radiation 2885
oncologist. You do not have to decide immediately if you want to participate, you can discuss the study with others and are provided 2886
with enough time to consider the possible benefits and disadvantages. 2887
In summary the main benefits and disadvantages of study participation are: 2888
The benefits of participating to this study are that external review and quality assurance of treatment planning and execution 2889
is part of the study and that you’re outcomes (tumor control and side effects of treatment) will be used to better understand 2890
how to improve this treatment further in the future. 2891
Having to fill in quality of life questionnaires may be seen as a disadvantage of participating to the study. 2892
127
Confidentiality 2893
You can be assured that all information that will be registered for this study will be handled confidential. Information that will be 2894
registered includes that of details of the treatment, details of the outcome on tumor control and side effects of treatment during the 2895
first five years after treatment. Before your data is sent to a central database anonymously, it will be coded using a unique study code. 2896
Only you’re treating radiation oncologist and any personnel that is directly authorized through you’re radiation oncologist will be able 2897
to see your information. 2898
Tumor tissue 2899
A small piece of tumor will be stored for future research. The tissue that was taken out to diagnose the cervical cancer can be used for 2900
this. This research will focus on finding alterations in the tissue that can help to better understand the outcomes of this study (effect of 2901
treatment on tumor control and side effects). The piece of tumor will be stored anonymously using you’re unique study code. You will 2902
be asked separately to provide signed written informed consent for the use of the tumor tissue. 2903
Financial support 2904
This study receives limited financial support from Varian and Electa, both are companies that produce radiation therapy equipment. 2905
This financial support is limited and is used for administration and database management and data analysis. None of the individual 2906
persons involved in the study receive financial support from these companies. 2907
Insurance 2908
Since the standard treatment is used in this study, there is no separate insurance policy for this study. In case of complaints or liability 2909
issues, the standard procedure as is used for any other medical treatment or condition in your hospital will apply. 2910
Further information 2911
If you have any other questions about this study you can ask your treating radiation oncologist, medical oncologist or gynecologist 2912
about these. [provide contact details and phone numbers, including an independent physician]. 2913
2914
2915
2916
2917
2918
128
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